A.  CRUISE NARRATIVE (P17C)

A.1  Highlights 

                        WHP Cruise Summary Information

                WOCE section designation  P17C
       Expedition designation (ExpoCode)  31WTTUNES_1

Chief Scientist(s) and their affiliation  Mizuki Tsuchiya, SIO
                                          Scripps Institution of Oceanography
                                          University of California San Diego
                                          9500 Gilman Drive
                                          La Jolla  CA  92093-0230       USA
                                          Phone: 858-534-323 Fax: 858-534-7452

                                   Dates  1991.05.31 - 1991.07.11
                                    Ship  R/V Thomas Washington
                           Ports of call  San Diego to Papeete, Tahiti
                                          with a stop at Port San Luis, CA
                      Number of stations  123

                                                     36°10.30'N
         Stations' Geographic boundaries  135°10.00'W             121°44.10'W
                                                      6°01.40'S

            Floats and drifters deployed  11 Floats and 4 Drifters
          Moorings deployed or recovered  0

                    Contributing Authors  L.D. Talley, M. Tsuchiya,
                                          M. Johnson, K.F. Sullivan,
                                          K.A. Maillet, F.M. Delahoyde,
                                          R.T. Williams, A Mantyla,
                                          R. Millard, R.M. Key


TABLE OF CONTENTS

Description of scientific program            | CTD - general
Geographic boundaries of the survey          | CTD - pressure
Cruise track (figure)                        | CTD - temperature
Description of stations                      | CTD - conductivity/salinity
Description of parameters sampled            | CTD - dissolved oxygen
Floats and drifters deployed                 |       Large Volume Sampling
Principal Investigators for all measurements |       Salinity
Cruise Participants                          |       Oxygen
Problems and goals not achieved              |       Nutrients
                                             |       CFCs
Underway Data Information                    |
                                             | DQE Reports
Navigation                                   |
Acoustic Doppler Current Profiler (ADCP)     |       CTD  
Meteorological observations                  |       S/O2/nutrients
                                             |       CFCs: 1st report 2nd report
Acknowledgments                              |       14C LV   14C AMS
                                             |
References: CTD  LVS  AMS  14C               | Data Status Notes



A.2.    CRUISE SUMMARY

A.2.a.  Cruise Track

R/V Thomas Washington departed San Diego on May 31, 1991 and occupied a test 
station north of Pt. Conception with the main purpose of testing the heave 
compensator. After the test station, the ship stopped at Port San Luis to 
exchange personnel and immediately proceeded northward to Station 1 at 36°10'N, 
121°44'W, where it turned to the southwest to make a line of stations roughly 
normal to the coast as far offshore as 34°35'N, 125°09'W (Station 9). From 
Station 9, the cruise track ran due west to 135°W (Station 17) and then turned 
to the south along 135°W. It extended southward across the equator, and the last 
station was occupied at 6°S, 135°W (Station 123). Near the equator, the track 
was shifted to the west by 10 nm to avoid a seamount. Thomas Washington arrived 
in Papeete, Tahiti on July 11.

The stations were spaced at intervals of 30 nm except near the California coast 
and the equator, where closer spacing was employed to resolve small-scale 
features. Along 34°35'N, however, the time constraint due to bad weather 
necessitated coarser spacing (see 4 below). The station locations are shown in 
Fig. 1.

A.2.b.  Sampling

Sampling was done primarily with use of a 36-place 10-liter bottle rosette. 
Water samples were collected for analyses of salt, oxygen, silicate, phosphate, 
nitrate, and nitrite on all stations and of CFC-11, CFC-12, 3helium, tritium, 
AMS 14C, alkalinity, and total dissolved inorganic carbon on selected stations. 
A smaller rosette with 11 bottles equipped with an ADCP was also used on 
alternate stations between 3°N and 3°S, where station spacing was 10 nm, but 
water sampling was limited to salt to calibrate the CTD. Large-volume sampling 
was made with use of 270-liter Gerard barrels for analyses of 14C, salt, and 
silicate on 9 stations spaced at intervals of about 50 of latitude along 135°W.

Separate surface water samples were also taken on 37 stations for analyses of 
226Ra, 228Ra, and Ba.

In addition to the on-station measurements mentioned above, a shipboard ADCP was 
continuously operated along the entire cruise track.

A.2.c.  The Number of Stations and Station Type

A total of 123 stations were occupied during the cruise. Of these, 104 were 
regular CTD/rosette stations, and 19 were ADCP/CTD stations within 30 of the 
equator without water sampling (except for salt samples for CTD calibration). On 
9 of the former, Gerard casts were also made for large-volume water sampling.


A.2.d.  Floats and Drifters Deployed

Eleven ALACE floats were deployed at 11 locations along 135°W, and 4 surface 
drifters were deployed at 4 locations near the equator and 135°W.

Sample                            Disp        Time
Code  Sample Identifier     Code  Date        UTC   Latitude  Longitude
----  --------------------  ----  ----------  ---   --------  ---------
CMDR  Drogue Drifter 15116  Por   June 23 91  2010  10.480N   135.030W
CDMR  Drogue Drifter 15112  Por   June 27 91  0010   5.000N   135.000W
CDMR  Drogue Drifter 15124  Por   July 01 91  1946   0.001N   135.010W
CDMR  Drogue Drifter 15110  Por   June 07 91  0710   5.013N   135.010W
CMRT  ALACE 58 SAT TRACKd   Por   June 11 91  0752  30.520N   134.960W
CMRT  ALACE 72 SAT TRACKd   Por   June 14 91  1138  26.030N   134.960W
CMRT  ALACE 53 SAT TRACKd   Por   June 16 91  0024  23.060N   135.000W
CMRT  ALACE 54 SAT TRACKd   Por   June 19 91  2153  16.990N   134.980W
CMRT  ALACE 29 SAT TRACKd   Por   June 22 91  1741  12.510N   134.970W
CMRT  ALACE 71 SAT TRACKd   Por   June 25 91  1052   7.995N   134.990W
CMRT  ALACE 60 SAT TRACKd   Por   June 27 91  0844   4.981N   134.940W
CMRT  ALACE 28 SAT TRACKd   Por   June 29 91  0659   2.170N   135.000W
CMRT  ALACE 62 SAT TRACKd   Por   July 01 91  2203   0.001S   135.140W
CMRT  ALACE 73 SAT TRACKd   Por   July 04 91         2.770S   135.003W
CMRT  ALACE 70 SAT TRACKd   Por   July 05 91         2.850S   135.010W


A.3  List of Prinicipal Investigators

Name                   Measurement Responsibility  Affiliation*
---------------------  --------------------------  ---------------
L. Talley/M. Tsuchiya  CTD/O2/Nutrients            SIO
R. Fine                CFCs                        Univ. of Miami
W. Jenkins             Helium/Tritium              WHOI
J. Lupton              Helium                      UCSB
R. Key                 14C/226Ra/228Ra/Ba          Princeton Univ.
C. Goyet/T. Takahashi  CO2                         WHOI/LDGO
L. Gordon              Nutrients                   OSU
C. Keeling             CO2                         SIO
E. Firing              ADCP                        Univ. of Hawaii
R. Davis               ALACE Floats                SIO
P. Niiler              Drifters                    SIO
                       Meterology                  SIO
                       Thermosalinograph  
R. Fine                Atmospheric Chemistry       RSMAS
                       Bathymetry  

A.4  Scientific Programme and Methods

Some of the preliminary results from this cruise are briefly described below:

1)  There was an indication of strong upwelling in a narrow strip within 30 km 
    of the California coast. Isopleths of all properties rose toward the shore, 
    and cold, low-oxygen, high-nutrient water apparently upwelled from a depth 
    of about 100 m was observed at the sea surface within this coastal strip. 
    However, the isopycnals (isotherms) below about 150 m deepened toward the 
    coast and suggested the presence of the poleward California Undercurrent.
2)  The highest surface temperature exceeding 28°C was observed between 12°N and 
    2.5°N. Farther south the sea-surface temperature decreased gradually but 
    remained above 27°C all the way to the southern end (6°S) of the section. 
    This surface temperature in the equatorial region is at least 1°C higher 
    than the normal temperature for July.
3)  The North Equatorial Countercurrent was clearly indicated by the equatorward 
    deepening of the thermocline from 8°N to 5°N. Farther south, an equatorward 
    dip of the 9-12°C isotherms suggested that the subsurface North Equatorial 
    Countercurrent was well developed. The Equatorial Undercurrent was indicated 
    by a trough of the isotherms in the lower portion of the thermocline at the 
    equator, but there was no evidence of a ridge of the isotherms in the upper 
    portion of the thermocline. The Undercurrent was also associated with an 
    isolated core of high salinity centered at 100 m, 1°S and an isolated core 
    of high oxygen centered at 140 m on the equator. A weak indication of the 
    subsurface South Equatorial Countercurrent was found at 200-400 m near 
    4°30'S in the temperature distribution.
4)  The coldest and densest bottom water (theta=1.006°C, sigma 4=45.900, 
    S=34.695) over the entire section was observed at 18°30'N about 200 km north 
    of the Clarion Fracture Zone. This water was high in salinity and oxygen and 
    low in nutrients and suggested an eastward flow of the bottom water from the 
    Central Pacific Basin. The saltiest (S=34.698) bottom water, also highest in 
    oxygen (O2=4.03 ml/l), was located near 4 S somewhat south of the Galapagos 
    Fracture Zone. Relatively cold, salty, oxygen-rich, nutrient-poor bottom 
    waters were also found at 24 N in the Molokai Fracture Zone and at 6 30'N in 
    the Cilpperton Fracture Zone. On the other hand, the bottom water within 
    about 30 of the equator was relatively warm, low in density and oxygen, and 
    high in nutrients. These meridional differences in the bottom water 
    characteristics may be due in part to the differences in the bottom depth 
    but in greater part appear to reflect the zonal flow pattern of the bottom 
    water.
5)  The vertical maximum of silicate, which is the major feature of the silicate 
    distribution in the Pacific Ocean, was observed at about 3000 m throughout 
    the present section. However, many (but not all) stations between 3°N and 
    3°S exhibited a weak minimum at about 3000 m, thus producing maxima at 2500 
    m and 3500 m. This double maximum structure of the silicate distribution 
    near the equator appears to be a real feature, but its cause and relation to 
    the circulation are not immediately obvious.


A.5  Major Problems Encountered on the Cruise

During the first week of the cruise, the bad weather that prevailed over the 
operation area made the handling of the CTD/rosette package difficult and slow. 
Because of the heavy rolling of the ship, the rosette could not be set up for a 
cast while underway and could be lowered only at a speed of 15-30 m/min. To 
avoid falling seriously behind schedule, it was necessary to increase the 
station spacing along 34°35'N (Stations 9-17) to 60 nm. Thus the WOCE 
specification of the 30 nm station spacing could not be met for this portion of 
the section.

The bad weather also was the main cause of a large number of bottle problems on 
stations 1-34, including bad trips, kinked wire, broken bottles and stopcocks.

A.6  List of Cruise Participants

M. Tsuchiya  Chief Scientist            
E. Firing    Co-Chief Scientist/ADCP    Univ. of Hawaii
M. Denham    Watch Stander              SIO
D. Muus      MT/Bottle data processing  SIO/ODF  SIO/ODF
T. Wells     MT/Salt                    SIO/ODF
J. Costello  Oxygen                     SIO/ODF
D. Bos       Nutrients                  SIO/ODF
L. Lopez     Large volume/Oxygen        SIO/ODF
C. Mattson   Electronic Technician      SIO/ODF
J. Jain      Salt                       SIO/ODF
A. Ross      Nutrients                  OSU
M. Johnson   CTD processing             SIO/ODF
K. Sullivan  CFCs                       Univ. of Miami
K. Casey     CFCs                       Univ. of Miami
R. Key       Large volume/AMS 14C       Princeton Univ.
W. Jenkins   Helium/Tritium             WHOI
K. Tedesco   Helium                     UCSB
S. Hacker    CO2                        WHOI
D. Breger    CO2                        LDGO
J. Moore     Computer Tech.             SIO/SCG
R. Comer     Resident Tech.             SIO/STS


B.   Underway Measurements 

B.1  Navigation

B.2  Acoustic Doppler Current Profiler (ADCP)

The ADCP that was run during this leg was an RD-VM150 153-kHz unit manufactured 
by RD Instruments and owned by Scripps. Raw data were logged on a PC and 
simultaneously on a SUN workstation. Position fixes provided by a Magnavox 4200 
GPS receiver were logged at the endof each 5-minute averaging interval 
("ensemble") on the PC, and at a 1-Hz rate on the SUN. The shipe's gyrocompass 
heading was input to the ADCP via a 1:1 synchro, and used for vector-averaging 
the velocity profiles in geographical coordinates. Heading error was calculated 
after the cruise from raw GPS data logged at 1 Hz from each of 2 Magnavox 4200D 
receivers, together witht he gyrocompass heading. These error calculations were 
crude and gappy, but did provide useful information that was used in 
postprocessing. The ADCP itself performed well apart from frequent failures 
during the first half of the cruise caused by ship's power glitches. The typical 
ADCP depth range was 300-400m.

The ADCP data have been processed using the Uniersity of Hawaii CODAS software 
package, as outlined in teh WHP Operations and Methods Manual. Processed data 
are archived on tampe in CODAS format at UH. Requests may be addressed to Eric 
Firing (efiring@soest.hawaii.edu: 808-956-7894)

B.3  Meterological Observations

Meterological observations where taken at each station. Information taken at 
each station included dominant wave direction, wind speed and direction, 
atmosperhic pressure, air temperature, weather, clouds and visiblity.


C.   Hydrographic Measurements

C.1    Description of Measurement Techniques and Calibrations

Extensive comments regarding calibration of both CTDs will be forthcoming from 
ODF. Sections B.1.1 and B.1.2, on the CTD data collection and processing, are 
incomplete, premature and possibly inaccurate and are based on notes taken by 
L.Talley during discussion with M. Johnson, the ODF CTD data processor. Discrete 
sample analysis text was supplied by ODF. The Oceanographic Data Facility's 
listing of bottle data comments which is included as section D could be of as 
much use to the DQEs as it was to us. Sections concerning the other measurements 
should be obtained from the relevant principal investigators.

C.1.a  CTD   (Lynne Talley)

Two NBIS Mark III CTDs were used. The first, designated CTD#1, was used for all 
stations except the alternate 10 nm stations between 3 N and 3 S. Because of the 
small station spacing in this zone, the length of time required to draw water 
from the 36-bottle rosette, and the perceived lack of need for water samples at 
10 nm resolution except for calibration of the CTD, the 36- bottle rosette with 
CTD#1 was alternated with a 12-bottle rosette with CTD#2. Only 11 bottles were 
used on the second rosette in order for a lowered ADCP to be attached to the 
rosette frame.

C.1.1  CTD#1

Temperature: two PRT's were mounted on the CTD. PRT1 was used for the 
temperature data throughout; PRT2 was available to use to check for drift, but 
this was not actually done. The pre-cruise calibration was 0.0028 C and 0.0023 C 
warmer (for warm and cold ends of the calibration, respectively) than the post-
cruise calibration but it was determined that the drift was not systematic and 
an average calibration was used. Temperature accuracy is therefore (0.0014 C to 
0.0011 C).

PRESSURE: 
One sensor was used throughout. There was a 3 dbar shift from pre to post-cruise 
calibration with no change in slope, so the difference is probably due only to 
initial offset in pressure. This is corrected for during calibration of each 
station, using the initial pressure. Pressure precision is 0.5 dbar after the 
pressure offset is removed according to the pressure model. In oceanic 
conditions, with changing temperature, the pressure error is smaller than 5 
dbar.

CONDUCTIVITY: 
There was no significant change in slope of conductivity as a function of delta 
C (difference between bottle and CTD conductivity), so one slope was applied to 
the whole cruise. There were four groups chosen for offsets:

Stas. 3-8: constant offset, ignoring stations 1,2,6
Stas. 9-30: sloping offset as function of stations, ignoring station 18
Stas. 31-67: constant offset
Stas. 68-123: constant offset

The data were very clean after station 30.

In looking at the data recently, we noted that there is a problem with an 0.001 
to 0.002 psu shift on many stations, at about 1.3-1.4 C (potential temperature). 
Stations which appear to have this after station 30 are: 31, 32, 33, 34, 35, 
(36,37), 39, 40, 42, 43, 45, 46, 47, 48, 49, 52, 54, (63??), 76, (78?), 80, 84, 
86, 88, 90, 92, 94, 98, 102, (118?), (123?). ODF is currently looking at these 
as part of the final documentation phase.

There are also some remaining bulges and spikes which might not be real: sta. 50 
(2638 dbar), 71 (3986 dbar).

C.1.2. CTD#2

CTD#2 was used on the 18 stations with odd numbers stating at 81 and ending at 
117. Bottle data to calibrate the casts was quite scanty; in retrospect we would 
advise concentrating more bottles in the lower 2000 meters, rather than on 
attempting to get a full profile. No water was collected from the bottles for 
any purpose other than conductivity calibration. Because the rosette 
configuration was new (owing to the use of the LADCP), there were many tripping 
problems caused by fouled lanyards at the start of the group of stations, so the 
number of calibration points is quite small at the outset.

TEMPERATURE: 
both PRT1 and PRT2 shifted at some point between pre-cruise calibration and 
station 183 on the next leg; the problem was first recognized during the 
following leg on which CTD#2 was used more extensively. (I'm not actually sure 
that this statement is correct - LDT.) At station 183, thermometers were added 
to the casts and thereafter helped in sorting out the problems enormously. It 
was then assumed that all of the PRT2 shift occurred after leg 1 and that there 
was also a shift in PRT1 between legs. The pre- cruise calibration was applied 
to PRT1 for the leg 1 data.

Pressure: 
the post-cruise calibration was 8 dbar lower than the pre-cruise CALIBRATION. 
There was only a 2 dbar offset during the cruise, so only the pre-cruise 
calibration was used. (I'm not clear about how this was known or decided.)

CONDUCTIVITY:
A slope which decreased as a function of station number was applied. Offsets 
were chosed using stations 99-117 and then extrapolated back. Fairly large 
individual station offsets were applied to several stations. Conductivity was 
somewhat noisy and there appears to have been a maintenance problem. The 
salinity offset problem on CTD#1 was not at all apparent on CTD#2, and this is 
the main reason for concluding that there was a sensor problem with CTD#1.

C.1.3. Comparison of CTD#1 and CTD#2 data:

Plots of salinity on isotherms and isopycnals shows a significant offset between 
CTD#1 and CTD#2, which is of the order of 0.001 psu at the cast bottom, and 
increases to 0.002 psu at about 2000 meters. CTD#1 is fresher than CTD#2 
throughout. Most of the change in offset occurs at the point where CTD#1 
conductivity has an offset of its own.

Because of the very low vertical gradients of salinity in the deep water, the 
consistent offset between CTD#1 and CTD#2 is easily apparent in a vertical 
section. Vertical sections of potential temperature and potential density are 
not affected.

Statistical differences between CTD#1 and CTD#2 salinities were estimated with

(1) differences in average salinity and pressure on isotherms for the station 
    range 80-118: CTD#1 is .001 to .003psu fresher than CTD#2 for temperatures 
    1.0 to 2.0 C, with the higher difference at 2.0 C.

(2) differences in average salinity, theta and pressure on isopycnals for the 
    station range 80-118: CTD#1 is 0.0008 to 0.002psu fresher than CTD#2 for the 
    isopycnal range 45.88 to 45.7 sigma 4, with the smaller differences at 
    higher density.

(3) average differences in adjacent stations' salinity and theta on isopycnals 
    45.88, 45.80 and 45.70 sigma 4: the results are very similar to (2), with 
    CTD#1 0.0008 to 0.002 psu fresher than CTD#1, with the smaller differences 
    at higher density. The difference in theta on these isopycnals is 0.003 to 
    0.008 C, with the higher difference at lower density.

Given that there is a systematic offset in salinity between CTD#1 and CTD#2 of 
0.001 to 0.002 psu below 2000 dbars, what is the effect on geostrophic velocity 
calculations? Using one station, dynamic height was computed at the surface 
relative to 4000 dbar with the original salinities, and then adding the same 
salinity offset to all bottles.

Adding 0.002 psu (i.e. higher salinity) increases the density, decreases the 
specific volume anomaly, and hence yields lower dynamic height, by 0.013 dynamic 
meters at the surface relative to 4000 dbar. The change is nearly linear in 
salinity error, so a 0.001 psu error would create half the dynamic height error. 
If geostrophic velocities are then calculated using the original station and the 
altered station, using various station spacings and latitudes, we can produce a 
table of velocity errors as a function of salinity error, station spacing and 
latitude.

For.002deltaS,the velocity error is (incm/sec):

                          1N  5N  10N  20N  30N   40N
                         ---  --  ---  ---  ----  ---
                  60 nm   20   4    2    1  .7     .6
                  30 nm   40   8    4    2   1.4  1.2
                  20 nm   60  12    6    3   2.1  1.8
                  10 nm  123  25   12    6   4.3  1.7


The result is of course exactly inversely proportional to station spacing. It is 
also nearly linear in delta S.

On transport errors: an error of 1 cm/sec over 1000m over 10nm (18.5 km) is 
equivalent to 0.185 Sv and a 100 cm/sec error therefore is equivalent to an 18.5 
Sv error.


C.2. BOTTLE DATA COLLECTION, ANALYSES, AND PROCESSING

Chief scientist comments: Bottle quality and data quality flags were first 
assigned by ODF and then examined by the chief scientists. After several 
iterations, we arrived at the set which are being sent with this documentation. 
We note that selection of quality flags posed some difficulties. In particular, 
there is no way to note that comments that there might have been a leak but 
where salinity, oxygen and nutrient values all appear to be fine; noting the 
potential problem could be important for the other analyses. The distinction 
between data quality which is questionable (flag = 3) and which is bad (flag = 
4) is also difficult in practice. Generally it was assumed with this data set 
that "bad" means that there was a fault noted with the actual analysis, and 
"questionable" means that the value is bad but no fault was noted with the 
actual analysis.

We, the chief scientists, strongly urge any users of this data to discard ANY 
value with a bottle data quality flag of 3, and any data quality flag of either 
3 or 4. "Questionable" data, flagged "3" does not mean "potentially good", 
rather it means bad but for unknown reasons. This comment is meant to clarify 
the comment in the ODF documentation which says that it is up to the scientists 
to decide whether to use data flagged as 3. When the level 2 data product is 
written and archived, no data with flags of either 3 or 4 should be archived. 
All bottle salts with these flags should be replaced with the CTD salts. 


C.3  Calibrated Pressure-Series CTD Data Processing Summary and Comments
     (Mary C. Johnson)
     August 31, 1993
                                                                 ODF CTD Group
                                                   Oceanographic Data Facility
                                           Scripps Institution of Oceanography
                                                  UC San Diego, Mail Code 0214
                                                             9500 Gilman Drive
                                                      La Jolla  CA  92093-0214

                                                      phone:    (619) 534-1906
                                                        fax:    (619) 534-7383
                                                     e-mail: mary@odf.ucsd.edu
1.  Introduction

In this document we discuss CTDO data acquisition, calibration,corrections, and 
other processing for the TUNES cruise, Legs 1 and 2,on the R/V Thomas 
Washington.  At various times during these legs, theCTD instruments and sensors 
exhibited more than the usual share ofnoise, drifts or other problems, making 
CTD data processing morechallenging than usual.  We believe that we have greatly 
reduced theuncertainty in the final reported values via careful examination 
andapplication of the pre- and post-cruise calibrations, and bycomparison of CTD 
data with the water sample and thermometric datacollected during the CTD casts.  
Our techniques and calibration dataare discussed below.

2.  CTD Acquisition and Processing Summary

221 CTD casts and 4 test casts were completed during TUNES Legs 1and 2.  The 
rosette used was an ODF-designed 36-bottle system with aring of twelve 10-liter 
bottles and 12- and 24-place General Oceanicspylons nested inside a ring of 
twenty-four 10-liter bottles.  A CTD,altimeter, pinger and transmissometer were 
mounted on the bottom ofthe frame.  ODF CTDs #1 and #2 (modified NBIS Mark III-B 
instruments)were used during both Legs 1 and 2.  CTD #10 was used on Leg 2 only.

Each ODF CTD acquired data at a maximum rate of 25 Hz.  The dataconsisted of 
pressure, temperature, conductivity, dissolved oxygen,second temperature, four 
CTD voltages, trip confirmation,transmissometer, altimeter and elapsed time.  
Power to the CTD wasoptimized by applying the minimum current to attain the CTD 
voltagesrequired to maintain sensor stability.  These voltages were 
monitoredthroughout the cast.

An ODF-designed deck unit demodulated the FSK CTD signal to anRS-232 interface.  
The raw CTD data server allowed the data to besplit into three different paths: 
to be logged in raw digitized form,to be monitored in real time as raw data, and 
to be processed andplotted.  During the TUNES expedition, an Integrated 
Solutions Inc.(ISI) Optimum V computer served as the real-time data acquisition
processor.  Additionally, Sun SPARC computers were used during post-cruise 
processing.

The raw CTD audio signal was recorded on VHS videotape as anultimate back-up, 
and all raw binary data were logged on a hard diskand then backed up to magnetic 
cartridge tape.  In addition, allintermediate versions of processed data were 
backed up to magneticcartridge tape.

CTD data processing consists of a sequence of steps which ismodified as needed.  
Data can be re-processed from any point in thissequence after the raw data are 
acquired from the sea cable andrecorded on videotape and/or hard disk.  Each CTD 
cast is assigned acorrection file, and while the corrections are usually 
determined forgroups of stations, it is possible to fine tune the parameters 
foreven a single station.  The acquisition and processing steps are asfollows:

 Data are acquired from the CTD sea cable and assembled into consecutive 
  .04-second frames containing all data channels.  The data are converted to 
  engineering units.
 The  raw  pressure,  temperature and conductivity data are passed through 
  broad absolute value and gradient  filters to eliminate noisy  data. 
  The entire frame of raw data is omitted, as opposed to interpolating bad 
  points, if any one of the filters is exceeded.  The filters may be 
  adjusted as needed for each cast.

                       TYPICAL TUNES RAW DATA FILTERS
       
                Raw Data    |       |       |Frame-to-Frame
                Channel     |Minimum|Maximum|   Gradient   
                ------------|-------|-------|--------------
                Pressure    |  -40  | 6400  |   2.0 dbar   
                ------------|-------|-------|--------------
                Temperature |  -8   | 32.7  |.2 to .6 deg.C
                ------------|-------|-------|--------------
                Conductivity|   0   |64.355 |.3 to .6 mmho 


 Pressure and conductivity are phase-adjusted to match the temperature 
  response, since the temperature sensor responds more slowly to change. 
  Conductivity data are corrected for ceramic compressibility in accordance 
  with the NBIS Mark III-B Reference Manual.
 The data are averaged into 0.5-second blocks.  During this step, data 
  falling outside four standard deviations from the mean are rejected and 
  the average is recalculated.  Then data falling outside two standard 
  deviations from the new mean are rejected, and the data are re-averaged. 
  The resulting averages, minus second temperature and CTD voltages, are 
  reported as the 0.5-second time series.  Secondary temperature data are 
  used to verify the stability of the primary temperature channel 
  calibration.  Secondary temperature data are only filtered, averaged and 
  reported with the time-series data when they are used in place of the 
  primary temperature data due to a sensor malfunction.
 Corrections are applied to the data.  The pressure data are corrected 
  using laboratory calibration data.  Temperature corrections, typically a 
  quadratic correction as a function of temperature, are based on laboratory 
  calibrations.  Conductivity and oxygen corrections are derived from water 
  sample data. Conductivity corrections are typically a linear fit as a 
  function of conductivity.  Oxygen data are corrected on an individual cast
  basis using the technique.  Uncorrected time-series transmissometer data are 
  forwarded to TAMU for final processing and reporting.

The averaged data are recorded on hard disk and sent to the real-time display 
system, where the averaged data can be reported andplotted during a cast.  The 
averaging system also communicates withthe CTD acquisition computer for 
detection of bottle trips, almostalways occurring during the up casts.  A 3- to 
4-second average of theCTD data is stored for each detected bottle trip.

A down-cast pressure-series data set is created from the timeseries by applying 
a ship-roll filter to the down-cast time-seriesdata, then averaging the data 
within 2-dbar pressure intervalscentered on the reported pressure.  The first 
few seconds of data foreach cast are generally excluded from the averages due to 
sensoradjustment or bubbles during the in-water transition.  Pressureintervals 
with no time-series data can optionally be filled by double-parabolic 
interpolation.  When the down-cast CTD data have excessivenoise, gaps or 
offsets, the up-cast data are used instead.  CTD datafrom down and up casts are 
not mixed together in the pressure-seriesdata because they do not represent 
identical water columns (due toship movement, wire angles, etc.).

The CTD time series is always the primary CTD data record for thepressure,  
conductivity  and  temperature channels.  The final correc-tions to the CTD 
oxygen data are made  by  correcting  pressure-seriesCTD  oxygen  data  to match 
the up-cast oxygen water samples at commonisopycnals.  The final CTDO pressure-
series data are the data reportedto the principal investigator and to the WHP 
Office.

Subsequent sections of this document discuss the laboratorycalibrations, data 
processing and corrections for each CTD used duringTUNES Legs 1 and 2.


3.    CTD Laboratory Calibrations

3.1.  Pressure Transducer Calibration

Each CTD pressure transducer was calibrated in a temperature-controlled bath to 
the ODF Ruska deadweight-tester (DWT) pressurestandards.  The mechanical 
hysteresis loading and unloading curveswere measured both pre- and post-cruise 
at cold temperature (-1.0 to0.1 degrees C bath) to a maximum of 8830 psi, and at 
warm temperature(29.4-30.2 degrees C bath) to a maximum of 1730-2030 psi.  The 
CTD-1pre-cruise calibration also included a cold calibration to 2030 psi aswell 
as a warm calibration to 8830 psi.

CTD #10 was not calibrated post-cruise because it flooded duringLeg 2 and was 
modified during repair.  CTD #1 and CTD #2 had partsinterchanged during Leg 2; 
these were put back in their originalconfigurations before their post-cruise 
calibrations.

CTD pre- and post-cruise pressure calibrations are summarized inFigures 1, 2 and 3.

3.2.  PRT Temperature Calibration

All CTD PRT temperature transducers were calibrated in atemperature-controlled 
bath.  CTD temperatures were compared withtemperatures calculated from the 
resistance of a standard platinumresistance thermometer (SPRT) as measured by a 
NBIS ATB-1250resistance bridge.  The ultimate temperature standards at ODF 
arewater and diphenyl ether triple-point cells and a gallium cell.  Sixor more 
calibration temperatures, spaced across the range of -2.0 to30.2 degrees C, were 
measured both pre- and post-cruise.

CTD pre- and post-cruise temperature calibrations are summarized in Figures 4, 5 and 6.


4.    CTD Data Processing

4.1.  Pressure, Temperature and Conductivity/Salinity Corrections

A maximum of 36 salinity and oxygen check samples were collectedduring each CTD 
cast.  Thermometric temperature data were alsomeasured at 1 or 2 levels per cast 
for stations 183 through 220 on Leg2.  No thermometric pressure data were 
collected.

A 3- to 4-second average of the CTD time-series data wascalculated for each 
sample.  The resulting data were then used toverify the pre- and post-cruise 
temperature calibrations, and toderive CTD conductivity/salinity and oxygen 
corrections.

Two CTDs were traded off during the equatorial section of Leg 1so that 11-bottle 
rosette casts with LADCP could alternate with36-bottle rosette casts.  During 
Leg 2, there were numerous CTDproblems and repair attempts that resulted in 
various sensors andinterfaces being shifted from one instrument to another.  
Thefollowing chart clarifies which sensors were being used for any givencast on 
Leg 1 or Leg 2:

    SUMMARY OF CTD SENSORS@ USED ON EACH PROCESSED TUNES CAST

CTD | Press. |  Temp.   | Cond. | STATIONS                                     
----|--------|----------|-------|----------------------------------------------
 1  |   1    | 1/PRT-1  |   1   | Leg1: 1-75,84-96even,98/2,100-116even,118-123
    |        |          |       | Leg2: 124-133,182,189,193-220                
----|--------|----------|-------|----------------------------------------------
 1  |   1    | 1s/PRT-1 |   1   | Leg1: 76-80,82                               
----|--------|----------|-------|----------------------------------------------
 1  |   1    | 1/PRT-1  |  1s   | Leg2: 134-136                                
----|--------|----------|-------|----------------------------------------------
 1  |   1    | 1/PRT-1  |  1.2  | Leg2: 190-192                                
----|--------|----------|-------|----------------------------------------------
 2  |   2    | 2/PRT-1  |   2   | Leg1: 81-97odd,98/4,99-117odd                
    |        |          |       | Leg2: 137-147                                
----|--------|----------|-------|----------------------------------------------
 2  |   2    | 2/PRT-2  |   2   | Leg2: 148-150,183-188                        
----|--------|----------|-------|----------------------------------------------
10  |   10   | 10/PRT-1 |  10   | Leg2: 151-181                                


@ Exact Sensor Serial numbers appear below:

     CTD |          |   Temperature   |                                 
     ID# | Pressure | PRT-1 |  PRT-2  | Conductivity                    
     ----|----------|-------|---------|---------------------------------
      1  |  131910  | 14304 | FSI1319 | 5902-F117                       
     ----|          |       |         |---------------------------------
     1s  |          |       | FSI1320 | spare (ser.no.unknown)          
     ----|          |       |         |---------------------------------
     1.2 |          |       |         | 5902-F117 | CTD-2 Cond.interface
     ----|----------|-------|---------|---------------------------------
      2  |  110188  | 15766 |  10680  | 2172-G147                       
     ----|----------|-------|---------|---------------------------------
     10  |  55504   | 16185 |  16188  | 2932-H137                       


4.1.1.    CTD Pressure Corrections

4.1.1.1.  CTD #1

CTD #1 pre- and post-cruise pressure calibrations, Figures 1a/band 1c, were 
compared.  The warm/shallow and cold/deep calibrationcurves both shifted by 
about 3 decibars from pre- to post-cruise.  Theslopes of the warm/shallow 
pressure calibration curves were nearlyidentical.  The slopes of the cold/deep 
curves were slightlydifferent:  shallower points were 1 decibar closer than 
deeper pointsfrom the two calibrations.  Thermometric pressures were not 
measuredduring either leg.

An average of the pre- and post-cruise pressure calibrations,Figure 1d, was 
calculated and applied to the CTD #1 pressure data fromboth legs.

4.1.1.2.  CTD #2

CTD #2 pre- and post-cruise pressure calibrations, Figures 2a and2b, were 
compared.  The warm/shallow and cold/deep calibration curvesboth shifted by 
about 8 decibars from pre- to post-cruise.  The slopesof the 2 sets of pressure 
calibration curves differed by a maximum of1 decibar over 6000 decibars.  
Thermometric pressures were notmeasured during either leg.

CTD #2 surface raw pressure data were compared over the course ofboth legs to 
determine when the 8-decibar shift might have occurred.CTD #2 was used on Leg 1 
for each LADCP cast: every other station from81 through 117.  There was no 
apparent shift in the surface rawpressures during this time:  all values, down 
or up cast, were within1 decibar of each other at equatorial surface 
temperatures.  These rawpressures were approximately halfway between the pre- 
and post-cruiselaboratory calibration values at similar temperatures.

The Leg 2 CTD #2 casts, stations 137-150 and 183-188, were alsochecked.  Down 
and up cast raw pressures were consistent and anaverage 2 decibars lower than 
the Leg 1 values, closer to the pre-cruise calibration than Leg 1.  There was no 
shift in raw pressurevalues between stations 150 and 183.

The pre-cruise calibration was left in place for the CTD #2pressure data on both 
legs because of negligible slope differencesbetween pre- and post-cruise 
calibrations.  Any residual offset wascompensated for automatically at each 
station: as the CTD enters thewater, the corrected pressure is adjusted to 0 
decibars.

4.1.1.3.  CTD #10

CTD #10 could not be calibrated post-cruise: the instrumentflooded during the 
first/aborted cast at station 182 and was subjectedto major repairs and 
adjustments after the cruise.  Any calibrationdata collected after this repair 
would not apply to the TUNES cruises.

Thermometric pressures were not measured during Leg 2.  The pre-cruise pressure 
calibration, Figure 3, remained in effect for the CTD#10 data on Leg 2.

4.1.2.    CTD Temperature Corrections

4.1.2.1.  CTD #1

CTD #1 had two temperature sensors: PRT-1 was calibrated pre- andpost-cruise; 
PRT-2 was only calibrated pre-cruise and was used tocheck for PRT-1 drift during 
the cruise.  A comparison of the pre- andpost-cruise laboratory CTD #1 PRT-1 
temperature transducercalibrations, Figures 4a and 4b, showed two curves with 
nearlyidentical slopes and a +.0025 deg.C temperature shift in the range of0 to 
32 deg.C.  An average of the two laboratory calibrations, Figure4c, was applied 
to the CTD #1 temperature data.

Thermometric temperature data from Leg 2, stations 189 through220, were compared 
to the calibrated CTD #1 temperature data.  Theaverage difference between 
thermometric data and final calibrated CTDdata was 0+/-.0005 deg.C, in good 
agreement with the averagelaboratory calibration used.
4.1.2.2.  CTD #2

CTD #2 also had two temperature sensors, each calibrated pre- andpost-cruise, 
Figures 5a/b (PRT-1) and 5c/d (PRT-2).  PRT-1, theprimary sensor, shifted an 
average +.044 deg.C between calibrations;PRT-2, the secondary sensor, shifted an 
average -.011 deg.C.  Theslopes also shifted by about .004 deg.C each over the 
30 deg.Ctemperature range of the calibrations.  The PRT-1 minus PRT-2difference 
changed by +.055 deg.C between calibrations at both coldand warm temperatures.


CTD #2 Laboratory Temperature Calibrations

      CTD #2 | Lab.Calib. | Std.-CTD|T (deg.C) |  Change   | Avg. Change
      Sensor |   Temp.    | Pre-crs | Post-crs | in Corrxn |  in CTD T  
      -------|------------|---------|----------|-----------|------------
      PRT-1  | 0 degC     | -1.486  |  -1.528  |   -.042   |            
             | 30 degC    | -1.496  |  -1.542  |   -.046   |    +.044   
      -------|------------|---------|----------|-----------|------------
      PRT-2  | 0 degC     | -1.497  |  -1.484  |   +.013   |            
             | 30 degC    | -1.495  |  -1.486  |   +.009   |    -.011   


PRT-1 drifting was first noticed during Leg 2, station 149, as apossible 
conductivity problem; PRT-1 temperature offsets as large as+.7 deg. C were noted 
during station 150.  After CTD #10 flooded andCTD #1 was under repair for 
continuing conductivity noise problems,CTD #2 was used again for stations 183-
188.  The secondary sensor wasused for CTD temperature data during these casts, 
and DSRT thermometerdata were collected to monitor any PRT-2 sensor drifting 
problems.

The two PRTs were monitored shipboard to check for drifting orother problems.  
At first glance, PRT-1 appeared to be stablethroughout the Leg 1 casts for which 
it was used; but PRT-1 minusPRT-2 differences had already shifted by 
approximately +.007 deg.Ccompared to the pre-cruise calibration.  Either sensor 
could haveshifted in its pre- to post-cruise direction to cause this 
change,which was 3 times the WOCE standard.

The two PRTs were compared by lagging the faster PRT-1 rawtemperature data by 
.15 seconds to match the PRT-2 raw data.  PRT-1minus PRT-2 differences were 
tabulated for Leg 1 and Leg 2 CTD #2casts to determine when temperature shifts 
occurred.  The PRT-1 datawas too unstable to use for the comparison beginning 
with station 148.The results of the comparison are as follows:


CTD #2 PRT-1 vs PRT-2 Comparisons

|                         |   Avg. PRT-1|minus PRT-2   |             
          Stations        | Warm/27degC | Cold/1.5degC | Avg. Change
          ----------------|-------------|--------------|------------
          Pre-crs calib.  |   +.001     |    -.011     |      -     
          Leg1,81-117     |   +.0075    |    -.0035    |   +.0070   
          Leg2,137-147    |   +.0285    |    +.0185    |   +.0215   
          Post-crs calib. |   +.056     |    +.044     |   +.0265   

The above comparison is only helpful if it can be determined wheneach PRT 
shifted.  Two thermometric temperature points per cast weremeasured on stations 
183-188 as a calibration check for PRT-2.  TheDSRT vs. PRT-2 comparisons 
indicate agreement with the post-cruisePRT-2 calibration.  The average residual 
DSRT-CTD difference afterapplying the post-cruise calibration is +.0034 deg.C, 
the closestdifference possible using either of the lab calibrations, or even 
acombination of the two.

PRT-2 had clearly shifted to the post-cruise temperaturecalibration by stations 
183-188, and corrections were appliedaccordingly.  The rest of the temperature 
corrections were determinedfrom this information, combined with clues provided 
by an apparentlystable CTD #2 conductivity sensor.

In an attempt to clarify when each sensor shifted, the CTD #2data from Leg 1 and 
Leg 2 were block-averaged two ways: using PRT-1 orPRT-2 temperature data to 
calculate CTD salinity.  PRT-2-basedsalinity corrections for stations 150/183 
were comparable using thepost-cruise temperature calibration.  Using this same 
PRT-2calibration for stations 137-150 also showed a smooth salinitypicture, 
indicating that PRT-2 had shifted to its post-cruisecalibration by the start of 
Leg 2.

PRT-2 was used for the primary temperature data for stations148-150 based on 
major shifts in conductivity slopes from 147 to 148when PRT-1 temperature data 
were used, and because of PRT-1temperature shifts observed during stations 149-
150.  PRT-2 was notlocated as near to the conductivity sensor as PRT-1, so it 
generatednoisier CTD salinity data: it was measuring slightly different waterand 
could not be matched properly to the conductivity sensor response.Because of 
this, PRT-1 was used for all CTD #2 data prior to station148, before it began to 
malfunction.

The PRT-1 minus PRT-2 difference was used to determine the Leg 2PRT-1 
calibration for stations 137-147.  The pre-cruise calibrationwas used, with an 
offset, because the strange behavior of PRT-1beginning at station 148 could have 
affected the post-cruisecalibration slope and it would not apply to earlier 
casts.  Theaverage pre- to post-cruise calibration drift for PRT-2 was -
.011deg.C; the average PRT-1 minus PRT-2 change from pre-cruise tostations 137-
147, for cold or warm temperatures, was .0285 deg.C.  AsPRT-2 drifted lower, 
increasing the difference by .011, PRT-1 had todrift higher; so the PRT-1 pre-
cruise calibration curve was decreasedby -.0175 deg.C for stations 137-147.  A 
smooth salinity correctionfor the PRT-1/PRT-2 transition at stations 147-148 
verified thisdecision.

The Leg 1 PRT-1 minus PRT-2 differences shifted an average +.0075deg.C, cold or 
warm, compared to the pre-cruise calibrations.  Nothermometer data was collected 
during this leg to verify which PRT(s)had changed since the pre-cruise 
calibration.  Salinity differences from the last CTD #2 casts of Leg 1 and the 
first CTD #2 casts fromLeg 2 were compared.  When the Leg 1 PRT-1 temperatures 
were correctedwith the pre-cruise calibration and a -.0075 deg.C offset, the 
Leg1/Leg 2 salinity differences were within .003 psu, a normal shiftafter any 
CTD has been on-deck and sitting idle for several weeks.This PRT-1 correction, 
which assumes that PRT-2 did its entire shiftbetween Legs 1 and 2, was used for 
all CTD #2 casts on Leg 1.

After Leg 2 conductivity/salinity corrections were calculated,there was up to a 
+.005 psu residual surface salinity offset forstations 143-147, indicative of an 
earlier PRT-1 problem thanpreviously thought.  Two options were considered: use 
PRT-2 fortemperature or use PRT-1 with an additional first-order T 
correction.Because of the noisy salt signal that results from using PRT-2, it 
wasdecided to use the added first-order T correction to PRT-1 forstations 143-
147.  This gave the best deep T/S data while pulling inthe surface differences.
A summary of the origin and correction of CTD #2 temperature  data  islisted 
below:


CTD #2 Temperature Correction Summary

        |                   | CTD #2 | Laboratory  | Calibration          
   Leg# | Stations          |  PRT#  | Calib. Used | Adjustment           
   -----|-------------------|--------|-------------|----------------------
    1   | 81-117odd + 98-4  | PRT-1  | Pre-cruise  | -.0075 offset        
    2   | 137-142           | PRT-1  | Pre-cruise  | -.0175 offset        
    2   | 143-147           | PRT-1  | Pre-cruise  | -.0175 offset plus   
        |                   |        |             | 1st-order T(T) corrxn
    2   | 148-150 + 183-188 | PRT-2  | Post-cruise | None                 


4.1.2.3.  CTD #10

CTD #10 had two temperature sensors, both calibrated pre-cruiseonly.  CTD #10 
could not be calibrated post-cruise: the instrumentflooded during the 
first/aborted cast at station 182 and was subjectedto major repairs and 
adjustments after the cruise.  Any calibrationdata collected after this repair 
would not apply to the TUNES cruises.

No thermometric temperatures were measured for this CTD.  ThePRT-1 minus PRT-2 
difference shifted -.002 deg.C from the pre-cruiselaboratory calibration, 
Figures 6a/b, to the first TUNES CTD #10 cast.The PRT difference changed by a 
maximum -.002 deg.C from the first tothe last CTD #10 cast (stations 151-181).  
The conductivity correctionshifted by more than .04 psu during this same time, a 
change 20 timesgreater than the PRT differences could account for.  The pre-
cruisecalibration notes for CTD #10 indicated that PRT-2 was unstable, so itwas 
assumed that any shift in the PRT difference was due to changes inPRT-2.  The 
pre-cruise PRT-1 temperature calibration, Figure 6a,remained in effect for the 
CTD #10 data on Leg 2.

4.1.3.  CTD Conductivity Corrections

In order to calibrate CTD conductivity, check-sampleconductivities were 
calculated from the bottle salinities using CTDpressures and temperatures.  For 
each cast, the differences betweensample and CTD conductivities at all pressures 
were fit to CTDconductivity using a linear least-squares fit.  Values greater 
than 2standard deviations from the fits were rejected.  The 
resultingconductivity correction slopes were plotted as a function of 
stationnumber.  The conductivity slopes were grouped by stations, based on
common PRT and conductivity sensor combinations, and then fit as afunction of 
station number to generate smoothed slopes for each group.These smoothed slopes 
were either averages of the slopes in thestation group (0-order) or changing by 
a fixed amount from station tostation (1st-order).

Conductivity differences were then calculated for each cast afterapplying the 
preliminary conductivity slope corrections.  Residualconductivity offsets were 
computed for each cast and fit to stationnumber.  Smoothed offsets were 
determined by groups as above, based oncommon PRT and conductivity sensor 
combinations.  The resultingsmoothed offsets were then applied to the data.  
Then conductivityslope as a function of conductivity was re-checked: no changes 
werewarranted.

Some offsets were manually adjusted to account for discontinuousshifts in the 
conductivity transducer response, or to insure aconsistent deep T-S relationship 
from station to station.

4.1.3.1.  Leg 1

CTD #1 and #2 were both used on Leg 1 without any apparentconductivity problems.  
They were mounted on different rosettes andused for opposite casts during the 
equatorial stations to allow foradequate sampling time on the larger rosette 
without loss of shiptime.  CTD #1 was on the 36-place rosette, while CTD #2 was 
on a12-place rosette with the LADCP.  Plots of the final Leg 1conductivity 
slopes and offsets can be found in Figures 7a and 8a.


Leg 1 Conductivity Correction Summary

Stations       | CTD# |       Cond.Slopes       |       Cond.Offsets@       
---------------|------|-------------------------|---------------------------
1-3            |  1   |       +3.4450e-4        |         +9.337e-3         
4-9            |  1   |       +3.4450e-4        |        +1.0837e-2         
9-30           |  1   |       +3.4450e-4        | -2.2706e-4*sta +1.3643e-2 
31-67          |  1   |       +3.4450e-4        | +4.9702e-5*sta +3.0220e-3 
68-96even,     |  1   |       +3.4450e-4        |        +7.7941e-3         
98/2,          |      |                         |                           
100-116even,   |      |                         |                           
118-123        |      |                         |                           
81-117odd,98/4 |  2   | -1.12e-5*sta +1.7936e-3 | +3.6617e-4*sta -7.2150e-2 
----------------------------------------------------------------------------
  @ individual stations were adjusted after this for conductivity sensor
    shifting or to insure a consistent deep T-S relationship from cast to cast.
    

4.1.3.2.  Leg 2

During Leg 2, the CTD #1 conductivity sensor had downcast noiseproblems of .005 
psu or larger beginning with station 133.  Theconductivity sensor was switched 
out for a spare before station 134,but the problem continued and actually 
tripled in size by station 136.Other CTDs were used until CTD #2's PRT problems 
and CTD #10'sflooding problems required trying CTD #1 again, with its 
originalconductivity sensor, at station 182; the noise problem continued.  CTD#2 
was again used for several stations until it locked up.

CTD #1 was brought back on line at station 189 as a mixture ofparts from CTDs #1 
and #2.  Following numerous repair attempts andpart switching, the culprit was 
discovered to be a coating on thePRT/Conductivity sensor guard that was flaking 
off and flapping infront of the sensor on the downcasts.  The coating was 
removed and there were no more noise problems beginning with station 197.  
Becauseof severe conductivity noise problems on their downcasts, the upcastswere 
used for stations 133-136, 182, and 189-196. Plots of the finalLeg 2 
conductivity slopes and offsets can be found in Figures 7b and8b.


Leg 2 Conductivity Correction Summary

         | Conduct.  |       Conductivity        |       Conductivity       
Stations | Sensor ID |          Slopes           |         Offsets@         
---------|-----------|---------------------------|--------------------------
124-133  |     1     |        +2.2324e-4         | +4.2845e-4*sta -4.8951e-2
134-136  |    1s     | -1.8377e-4*sta -1.3375e-2 | +6.5794e-3*sta -8.7711e-1
137-147  |     2     | -2.5674e-5*sta +3.7912e-3 | +1.4006e-3*sta -2.1403e-1
148-150, |     2     | +2.9952e-6*sta -1.0495e-4 | -1.0969e-4*sta -1.9537e-3
183-188  |           |                           |                          
151-181  |    10     | -1.1894e-5*sta +2.2683e-3 | +2.0299e-4*sta -3.1279e-2
182,189, |     1     | +1.6366e-5*sta -3.7327e-3 | -5.0723e-4*sta +1.1454e-1
193-196  |           |                           |                          
190-192  |    1.2    | +2.0127e-4*sta +1.0515e-2 |  -6.59775e-3*sta +1.2534 
197-220  |     1     |        -6.5218e-4         |        +8.19092e-3       
----------------------------------------------------------------------------
   @ individual stations were adjusted after this for conductivity sensor
     shifting or to insure a consistent deep T-S relationship from cast to cast.


4.1.3.3.  Bottle vs. CTD Conductivity Statistical Summary

The TUNES calibrated bottle-minus-CTD conductivity statistics in-clude bottle 
salinity values with quality 3 or 4.  There is approxi-mately a 1:1 
correspondence between conductivity and salinity residualdifferences.  The 
following statistical results were generated fromthe final bottle data set and 
the final corrected CTD data:


TUNES Final Bottle-CTD Conductivity Statistics

         |                 |  mean conductivity   |           |        
 cruise  |    pressure     |      difference      | standard  | #values
   leg   |  range(dbars)   | (bottle-CTD mmho/cm) | deviation | in mean
 --------|-----------------|----------------------|-----------|--------
 TUNES-1 | all pressures   |      -.00053@@       |   .01357  |  3819  
         | allp (4,2rej) @ |       .00033         |   .00365  |  3566  
         |-----------------|----------------------|-----------|--------
         | press < 1500    |      -.00077         |   .01741  |  2230  
         | p<1500(4,2rej)@ |       .00040         |   .00609  |  2081  
         |-----------------|----------------------|-----------|--------
         | press > 1500    |      -.00019@@@      |   .00412  |  1589  
         | p>1500(4,2rej)@ |       .00012         |   .00128  |  1527  
 --------|-----------------|----------------------|-----------|--------
 TUNES-2 | all pressures   |       .00013@@       |   .03991  |  3449  
         | allp (4,2rej) @ |       .00003         |   .00355  |  3310  
         |-----------------|----------------------|-----------|--------
         | press < 1500    |       .00016         |   .05191  |  2036  
         | p<1500(4,2rej)@ |      -.00012         |   .00566  |  1953  
         |-----------------|----------------------|-----------|--------
         | press > 1500    |       .00007@@@      |   .00242  |  1413  
         | p>1500(4,2rej)@ |      -.00010         |   .00084  |  1359  
 ----------------------------------------------------------------------
  @ "4,2rej" means a 4,2 standard-deviation rejection filter was applied to the 
    differences before generating the results. 
 @@ Plots of these differences can be found in Figures 9a and 9b.
@@@ Plots of these differences can be found in Figures 10a and 10b.


4.2.  CTD Dissolved Oxygen Data

4.2.1.  CTD Oxygen Corrections

Dissolved oxygen data were acquired using Sensormedics dissolvedoxygen sensors.  
During TUNES Legs 1 and 2, two oxygen sensors wereused.  Sensor A was used with 
all CTDs for every station except188-192, where it was temporarily replaced with 
sensor B because ofoxygen signal problems.

CTD oxygen data are corrected after pressure, temperature andconductivity 
corrections have been determined.  CTD raw oxygencurrents were extracted from 
the pressure-series data at isopycnalscorresponding to the up-cast check 
samples.  Most pressure-series datawere from the down casts, where oxygen data 
are usually smoother thanup-cast data because of the more constant lowering 
rate, avoiding theflow-dependence problems occurring at up-cast bottle stops.  
However,the TUNES CTD oxygen data were affected with flow-dependence 
problems,down or up cast, each time a cast was stopped for several minutesaround 
20 decibars to activate/de-activate the heave compensator.

The CTD oxygen correction coefficients were determined byapplying a modified 
Levenberg-Marquardt nonlinear least squaresfitting procedure to residual 
differences between CTD and bottleoxygen values.  Bottle oxygen values were 
weighted as required tooptimize the fitting of CTD oxygen to discrete bottle 
samples.  Some bottle levels were omitted from a fit because of large 
pressuredifferences between down- and up-cast CTD data at isopycnals.  Deepdata 
points were often weighted more heavily than shallower data dueto the higher 
density of shallow sampling on a typical 36-bottlesampling scheme.

The TUNES surface oxygen data fitting was adversely affected bythe long heave 
compensator stop which, combined with the typicalgoing-in-water bubbles/noise, 
made it difficult to fit CTD oxygens tothe bottle data in the surface mixed 
layer of many casts.

4.2.2.  Bottle vs. CTD Oxygen Statistical Summary

The CTD oxygens are generated by fitting up cast oxygen bottledata to down cast 
CTD raw oxygen (microamps) measurements along isopy-cnals.  Residual oxygen 
differences are not generated from these com-parisons, so no comparison 
statistics are shown in this report.


4.3.  Additional Processing

A software filter was used on 36 Leg1 casts and 40 Leg2 casts toremove 
conductivity or temperature spiking problems in about 0.1% ofthe time-series 
data frames.  Pressure did not require filtering.  Afourth of the T/C spiking 
problems occurred in station 182, andanother fourth were concentrated in the 
CTD-2/PRT-2 casts, where thedistance between the secondary PRT and the 
conductivity sensorresulted in poor signal matchup in high-gradient areas.

Oxygen spikes were filtered out of 2 Leg1 casts and 91 Leg2casts; software 
improvements prior to the Leg2 oxygen processingenabled this large difference in 
oxygen filtering.  The filteredoxygen levels affected approximately 2.5% of the 
time-series dataframes.  76% of the filtered oxygen data were shallower than 100 
dbarsand could be directly related to the stop at the heave 
compensatoractivation/de-activation, or bubbles trapped during the going-in-
watertransition.

The remaining density inversions in high-gradient regions cannotbe accounted for 
by a mis-match of pressure, temperature andconductivity sensor response.  
Detailed examination of the raw datashows significant mixing occurring in these 
areas because of shiproll.  The ship-roll filter resulted in a reduction in the 
amount andsize of density inversions.

After filtering, the down cast (or up cast - see table below)portion of each 
time-series was pressure-sequenced into 2-decibarpressure intervals.  A ship-
roll filter was applied to each castduring pressure sequencing to disallow 
pressure reversals.  The heavecompensator installed on the R/V Washington 
decreased the magnitude ofshiproll effects to a level comparable to 
Melville/Knorr CTD casts.


5.  General Comments/Problems

There is one pressure-sequenced CTD data set, to near the oceanfloor, for each 
of 221 casts at 220 station locations.  There was anextra CTD cast at station 
98, the equator station for Leg 1, tocollect LADCP data.  There were four 
additional equipment test casts,plus four casts aborted because of various CTD 
problems; these wereneither processed nor reported.  Another CTD cast was done 
immediatelyafter any aborted cast at the same location.



The data reported is from down casts, excepting the stationslisted below:


UP-CAST PRESSURE-SERIES DATA REPORTED

           Leg# | Station(s)          | Problem with Down Cast Data
           -----|---------------------|----------------------------
            1   | 16                  | VCR-operator error 800-1100
                |                     | dbar down, data not record-
                |                     | ed/lost; up ok             
           -----|---------------------|----------------------------
            2   | 133-136,182,189-196 | Conductivity sensor guard  
                |                     | coating flaking off, caus- 
                |                     | ing noisy conductivity sig-
                |                     | nal on down casts, much    
                |                     | less noise on up casts.    
                |                     | Problem resolved before    
                |                     | station 197.               

The 0-2 decibar level(s) of some casts were extrapolated using aquadratic fit 
through the next three deeper levels.  Recorded surfacevalues were rejected only 
when it appeared that the drift was causedby sensors adjusting to the in-water 
transition; if there were anyquestion that the that the surface values might be 
real, the originaldata was reported.  Extrapolated surface levels are identified 
by acount of "1" in the "Number of Raw Frames in Average" reported witheach data 
record on the tapes.

Several shipboard time-series data sets had areas of missing ornoisy data.  
These casts were recovered by re-digitizing the rawsignal from analog tape.  The 
top 8 db of one Leg1 cast and 4 non-surface data levels in 2 Leg2 casts were 
interpolated.  The pressuresfor these interpolated data frames as well as other 
cast-by-castshipboard or processing comments are listed in the "CTD 
ProcessingComments" in Appendix D.  All interpolated data levels have a count 
of"1" in the "Number of Raw Frames in Average" column in the data files.

In addition, missing data values, such as CTD oxygens in castswhere the sensor 
failed, are represented as "-9" in the data files.There were two casts (stations 
183-184) where the oxygen signal failedonly during the top 200 decibars; these 
are not reported as "-9", butthe affected pressures are listed in Appendix D.

The CTD oxygen sensor often requires several seconds in the waterbefore being 
wet enough to respond properly; this is manifested as lowor high CTD oxygen 
values at the start of some casts.  Flow-dependenceproblems occur when the 
lowering rate varies, or when the CTD isstopped, as at the cast bottom, bottle 
trips or the heave-compensatoractivation, where depletion of oxygen at the 
sensor causes loweroxygen readings.  Station 133 oxygen data demonstrate a 
typical oxygendepletion effect at each bottle stop.  Delays and yoyos during 
thecasts are documented in Appendix D.


C.2  Gerard Bottles

Gerard pressures and temperatures were calculated from Deep-Sea Reversing 
Thermometer (DSRT) readings. Each DSRT rack normally held 2 protected 
(temperature) thermometers and 1 unprotected (pressure) thermometer. 
Thermometers were read by two people, each attempting to read a precision equal 
to one tenth of the thermometer etching interval. Thus, a thermometer etched at 
0.05 degree intervals would be read to the nearest 0.005 degrees. Each 
temperature value is therefore calculated from the average of four readings 
provided both protected thermometers function normally.

The temperatures are based on the International Temperature Scale of 1990.

C.3  Salinity

Salinity samples were drawn into 200ml Kimax high-alumina borisilicate bottles 
with custom-made plastic insert thimbles and Nalgene screw caps. This assembly 
provides very low container dissolution and sample evaporation. Salinity bottles 
were rinsed three times before filling. Salinity was determined after sample 
equilibration to laboratory temperature, usually within about 8-36 hours of 
collection. Salinity has been calculated according to the equations of the 
Practical Salinity Scale of 1978 (UNESCO, 1981). This calculation uses the 
conductivity ratio determined from bottle samples analyzed (minimum of two 
recorded analyses per sample bottle after flushing) with a Guildline Autosal 
Model 8400A salinometer. The salinometer was standardized against Wormley P-114 
standard seawater, with at least one fresh vial opened per cast.

Accuracy estimates of bottle salinities run at sea are usually better than 0.002 
psu relative to the specified batch of standard. Although laboratory precision 
of the Autosal can be as small as 0.0002 psu when running replicate samples 
under ideal conditions, at sea the expected precision is about 0.001 psu under 
normal conditions, with a stable lab temperature.

C.4  Oxygen

Samples were collected for dissolved oxygen analyses soon after the rosette 
sampler was brought on board and after CFC and Helium were drawn. Nominal 100 or 
125 ml volume iodine flasks were rinsed carefully with minimal agitation, then 
filled via a drawing tube, and allowed to overflow for at least 2 flask volumes. 
Reagents were added to fix the oxygen before stoppering. The flasks were shaken 
twice; immediately after drawing, and then again after 20 minutes, to assure 
thorough dispersion of the Mn(OH)2 precipitate. The samples were analyzed within 
4-36 hours.

Dissolved oxygen samples were titrated in the volume-calibrated iodine flasks 
with a 1 ml microburet, using the whole-bottle Winkler titration following the 
technique of Carpenter (1965) with modifications by Culberson et. al. (1991). 
Standardizations were performed with 0.01N potassium iodate solutions prepared 
from preweighed potassium iodate crystals. Standards were run at the beginning 
of each session of analyses, which typically included from 1 to 3 stations. 
Several standards were made up and compared to assure that the results were 
reproducible, and to preclude basing the entire cruise on one standard, with the 
possibility of a weighing error. A correction was made for the amount of oxygen 
added with the reagents. Combined reagent/seawater blanks were determined to 
account for oxidizing or reducing materials in the reagents, and for a nominal 
level of natural iodate (Brewer and Wong, 1974) or other oxidizers/reducers in 
the seawater. These latter corrections are contrary to the recommendations of 
Culberson et al. (1991), which call for the determination of reagent blanks in 
distilled water. ODF standard procedures have since been aligned with those 
recommended by Culberson.

Oxygens were converted from milliliters per liter to micromoles per kilogram 
using the in-situ temperature. Ideally, for whole-bottle titrations, the 
conversion temperature should be the temperature of the water issuing from the 
Niskin bottle spigot. The temperature of the samples was measured at the time 
the sample was drawn from the bottle, but were not used in the conversion from 
milliliters per liter to micromoles per kilogram because the software was not 
available. Aberrant temperatures provided an additional flag indicating that a 
bottle may not have tripped properly. Measured sample temperatures from mid-deep 
water samples were about 4-7°C warmer than in-situ temperature. Converted oxygen 
values, if this conversion with the measured sample temperature were made, would 
be about 0.08% higher for a 6°C warming (or about 0.2µm/kg for a 250µm/kg 
sample.)

C.5  Nutrients

Nutrients (phosphate, silicate, nitrate and nitrite) analyses, reported in 
micromoles/kilogram, were performed on a Technicon AutoAnalyzer(r). The 
procedures used are described in Hager et al. (1972) and Atlas et al. (1971). 
Standardizations were performed with solutions prepared aboard ship from 
preweighed standards; these solutions were used as working standards before and 
after each cast (approximately 36 samples) to correct for instrumental drift 
during analyses. Sets of 4-6 different concentrations of shipboard standards 
were analyzed periodically to determine the linearity of colorimeter response 
and the resulting correction factors. Phosphate was analyzed using hydrazine 
reduction of phosphomolybdic acid as described by Bernhardt & Wilhelms (1967). 
Silicate was analyzed using stannous chloride reduction of silicomolybdic acid. 
Nitrite was analyzed using diazotization and coupling to form dye; nitrate was 
reduced by copperized cadmium and then analyzed as nitrite. These three analyses 
use the methods of Armstrong et al. (1967).

Sampling for nutrients followed that for the tracer gases, CFC's, He, Tritium, 
and dissolved oxygen. Samples were drawn into ~45 cc high density polyethylene, 
narrow mouth, screw-capped bottles which were rinsed twice before filling. The 
samples may have been refrigerated at 2 to 6°C for a maximum of 15 hours.

Nutrients were converted from micromoles per liter to micromoles per kilogram by 
dividing by sample density calculated at an assumed laboratory temperature of 
25°C.

C.6  Chlorofluorocarbons 
     (Kevin F. Sullivan and Kevin A. Maillet)

Concentrations of the dissolved atmospheric cholorfluorocarbons (CFCs) F-11 and 
F-12 were measured by shipboard electron-capture gas chromatography according to 
the methods described by Bullister and Weiss (1988). The measurements were 
carried out by the group at the University of Miami under the direction of Dr. 
Rana A. Fine. A total of 1627 water analyses were carried out, 9 of which were 
duplicate analyses as tabulated in Table B.8.1. The mean value of duplicate 
analyses are reported in the data file and are assigned a quality byte of 6.

Several times during the cruise, problems with the analytical system required 
extensive downtime. If samples were drawn, but not analyzed, and the downtime 
exceeded 6 to 8 hours, some or all of these samples were discarded and fresh 
samples were drawn on the current station. This situation occurred after 
stations 16 and 24. In accordance with WHP protocol, the value for these 
analyses has been reported as -9.000 and they have been assigned a quality byte 
of 5. After station 46, the analysis of the samples was delayed 3 hours while a 
problem was eliminated.

On a number of occasions, the CFC analysis appeared routine yet the values 
obtained were clearly inappropriate based on the depth at which the Niskin was 
tripped. Upon further inspection it was noticed that there appeared to be 
problems with other measured quantities from these bottles as well. While the 
groups reporting hydrography and nutrients have chosen to eliminate the data in 
these situations, this group will report the data as measured and have assigned 
a data qulity flag of 4 to the quality byte for that measurement. It is 
considered that this is more in keeping with the WHP standard protocol that all 
data should be reported. In our view, the quality byte assigned to the bottle 
itself should be changed to 4 and the measured data retained. Situations where 
this occurred were:

S(tation) 6, N(iskin) 5; S 7, N 1; S 9, N 5 & 6; S 10, N 5 & 6; S 31, N 6.

The following analyses are suspect in relation to the surrounding values and 
have been flagged as bad data (quality byte 4):

S 10, N 33, F11; S 14, N 33, F11; S 61, N 6 & 7, F12; S 98, N 23, F12; S 122, N 18, F11.

A combination bottle and handling blank was used to correct for contamination 
from the Niskin bottles and from the collection and storage of the samples. This 
blank was estimated by analyzing samples from Niskins after they were tripped in 
what is believed to be CFC-free water. Since it is common for the blank arising 
from the Niskin bottles to be higher at the beginning of a cruise and to become 
progressively lower throughout the cruise, blanks were estimated over ranges of 
stations and applied to water analyses occurring during these ranges. In cases 
where the bottle/handling blank is greater than the measured concentration, a 
negative concentration is reported in the data file. A list of all Niskins and 
their bottle/handling blanks over the entire cruise is included in Table B.8.2.

Measurements of the atmospheric concentration of F-11 and F-12 were carried out 
regularly during the cruise. Air samples were pumped through a Decabond tubing 
air line run along the railing of the ship and up the mast at the bow. Air 
measurements were usually carried out while on station when the bow of the ship 
was heading into the wind to avoid contamination from the stack. Usually, three 
to six air measurements were carried out in sequence. The mean values of 
replicate air analyses are tabulated in Table B.8.3


Table B.8.1.  Duplicate water analyses (duplicate syringes drawn on same niskin)
 
                                             AvgF12  AvgF11
           Stn# Nsk# Dpth  pM12/kg  pM11/kg  StdDev  StdDev
           ---- ---- ----  -------  -------  ------  ------
             6  11    250   0.889    2.026   0.8897  2.0235
             6  11    250   0.890    2.021   0.0008  0.0030
             6  36   4082   0.034    0.008   0.0334  0.0080
             6  36   4082   0.032    0.008   0.0011  0.0001
            20  15    600   0.071    0.133   0.0717  0.1336
            20  15    600   0.072    0.134   0.0002  0.0002
            26  13    600   0.149    0.268   0.1414  0.2573
            26  13    600   0.133    0.247   0.0079  0.0103
            37  14    500   0.102    0.180   0.1040  0.1800
            37  14    500   0.106    0.180   0.0022  0.0003
            63  11    350   0.029    0.025   0.0283  0.0258
            63  11    350   0.028    0.026   0.0005  0.0005
            82  13    300   0.133    0.247   0.1329  0.2461
            82  13    300   0.132    0.246   0.0005  0.0005
           104  13    350   0.051    0.088   0.0507  0.0881
           104  13    350   0.050    0.089   0.0006  0.0006
           112  12    300   0.124    0.211   0.1230  0.2102
           112  12    300   0.122    0.209   0.0014  0.0012


Table B.8.2.  Bottle/handling blanks applied to P17c/TUNES 1 water analyses

     ***CFC 11*** P17c/TUNES 1       ||       ***CFC 12*** P17c/TUNES 1 
-------------------------------------||----------------------------------------
      |        Station #             ||        |         Station #    
      |----------------------------  ||        |-------------------------------
Niskin|  1-9 | 10-26| 27-45| 46-123  ||  Niskin|  1-9  | 10-26 | 27-45 | 46-123
   1  | 0.003| 0.003| 0.003| 0.003   ||     1  | 0     | 0     | 0     | 0
   2  | 0.005| 0.005| 0.005| 0.005   ||     2  | 0.002 | 0.002 | 0.002 | 0.002
   3  | 0.003| 0.003| 0.003| 0.003   ||     3  | 0     | 0     | 0     | 0
   4  | 0.003| 0.003| 0.003| 0.003   ||     4  | 0.002 | 0.002 | 0.002 | 0.002
   5  | 0.003| 0.003| 0.003| 0.003   ||     5  | 0.003 | 0.003 | 0.003 | 0.003
   6  | 0.003| 0.003| 0.003| 0.003   ||     6  | 0.003 | 0.003 | 0.003 | 0.003
   7  | 0.005| 0.005| 0.005| 0.005   ||     7  | 0.003 | 0.003 | 0.003 | 0.003
   8  | 0.003| 0.003| 0.003| 0.003   ||     8  | 0     | 0     | 0     | 0
   9  | 0.003| 0.003| 0.003| 0.003   ||     9  | 0     | 0     | 0     | 0
  10  | 0.003| 0.003| 0.003| 0.003   ||    10  | 0     | 0     | 0     | 0
  11  | 0.004| 0.004| 0.004| 0.004   ||    11  | 0     | 0     | 0     | 0
  12  | 0.003| 0.003| 0.003| 0.003   ||    12  | 0.003 | 0.003 | 0.003 | 0.003
  13  | 0.006| 0.003| 0.003| 0.002   ||    13  | 0.004 | 0.002 | 0.002 | 0.002
  14  | 0.006| 0.003| 0.003| 0.002   ||    14  | 0.004 | 0.002 | 0.002 | 0.002
  15  | 0.006| 0.003| 0.003| 0.002   ||    15  | 0.004 | 0.002 | 0.002 | 0.002
  16  | 0.006| 0.004| 0.004| 0.003   ||    16  | 0.004 | 0.003 | 0.003 | 0.003
  17  | 0.006| 0.004| 0.004| 0.003   ||    17  | 0.004 | 0.003 | 0.003 | 0.002
  18  | 0.006| 0.003| 0.003| 0.002   ||    18  | 0.004 | 0.002 | 0.002 | 0.002
  19  | 0.006| 0.003| 0.003| 0.002   ||    19  | 0.004 | 0.002 | 0.002 | 0.002
  20  | 0.009| 0.005| 0.005| 0.004   ||    20  | 0.006 | 0.004 | 0.003 | 0.003
  21  | 0.009| 0.005| 0.002| 0.002   ||    21  | 0.006 | 0.004 | 0     | 0
  22  | 0.009| 0.005| 0.003| 0.003   ||    22  | 0.006 | 0     | 0     | 0
  23  | 0.009| 0.005| 0.003| 0.003   ||    23  | 0.006 | 0     | 0     | 0
  24  | 0.009| 0.005| 0.003| 0.003   ||    24  | 0.006 | 0     | 0     | 0
  25  | 0.009| 0.004| 0.002| 0.002   ||    25  | 0.006 | 0     | 0     | 0
  26  | 0.009| 0.004| 0.002| 0.002   ||    26  | 0.006 | 0     | 0     | 0
  27  | 0.009| 0.004| 0.002| 0.002   ||    27  | 0.006 | 0     | 0     | 0
  28  | 0.009| 0.004| 0.002| 0.002   ||    28  | 0.006 | 0     | 0     | 0
  29  | 0.009| 0.003| 0.003| 0.002   ||    29  | 0.006 | 0     | 0     | 0
  30  | 0.009| 0.003| 0.003| 0.002   ||    30  | 0.006 | 0     | 0     | 0
  31  | 0.009| 0.004| 0.004| 0.003   ||    31  | 0.006 | 0     | 0     | 0
  32  | 0.009| 0.003| 0.003| 0.002   ||    32  | 0.006 | 0     | 0     | 0
  33  | 0.009| 0.004| 0.002| 0.002   ||    33  | 0.006 | 0.004 | 0     | 0
  34  | 0.009| 0.004| 0.004| 0.002   ||    34  | 0.006 | 0.004 | 0     | 0
  35  | 0.009| 0.005| 0.004| 0.002   ||    35  | 0.006 | 0.005 | 0     | 0
  36  | 0.009| 0.005| 0.004| 0.003   ||    36  | 0.006 | 0.005 | 0     | 0


Table B.8.3.  Air analyses carried out during P17c/TUNES1

                    Lat. along 135W  ppt F12  ppt F11
                    ---------------  -------  -------
                    34.1 N            490.9    274.9
                    30.5 N            489.4    271.5
                    30.0              492.8    274.1
                    26.5 N            503.8    277.0
                    26.0              501.7    276.0
                    22.5 N            500.0    275.5
                    22.0              496.2    274.2
                    18.0 N            494.8    272.6
                    16.5              498.6    276.8
                    14.0 N            486.9    271.3
                    12.5              497.5    279.9
                     9.5 N            495.3    271.6
                     6.5              486.6    269.5
                     4.0 N            495.2    268.3
                     2.7              478.9    266.4
                     1.3 N            483.0    266.1
                     0.3 S            481.2    270.3
                     2.0 S            481.3    267.8
                     3.0 S            474.1    265.1
                     3.5 S            476.6    268.4
                    16.2 S  148.1 W   483.3    262.6


C.7  BOTTLE DATA COMPARISONS AND COMMENTS

The oxygen and nutrient data were compared by ODF with those from the adjacent 
station. Dr. Mizuki Tsuchiya and Dr. Lynne Talley did comparisons with 
historical data sets.

Cruise 31WTTUNES/1 had several start-up problems, due to moderately rough 
weather, pylon problems, and the close spacing of the initial run of stations. 
Until the pylon problems were sorted out, there were substantial portions of the 
water column without verifiable water samples. Most closure problems were solved 
by the time the vessel began the WOCE run along 135°W.

Post cruise assessment revealed that the practice of renumbering replacement 
Niskin bottles (to keep numbers in sequence), was at least occasionally followed 
on this cruise leg. This goes against ODF and WOCE policy. it may be possible to 
reconstruct bottle numbering history for this cruise leg, but at significant 
cost (the deck log is occasionally vague on this point), and so no changes have 
yet been made to the bottle numbers as reported from the shipboard data file.


D.  REFERENCES AND UNCITED SUPPORTING DOCUMENTATION

Armstrong, F. A. J., C. R. Stearns, and J. D. H. Strickland, 1967. The 
    measurement of upwelling and subsequent biological processes by means of the 
    Technicon Autoanalyzer and associated equipment, Deep-Sea Research 14, 381-
    389.

Atlas, E. L., S. W. Hager, L. I. Gordon and P. K. Park, 1971. A Practical Manual 
    for Use of the Technicon(R) AutoAnalyzer(R) in Seawater Nutrient Analyses; 
    Revised. Technical Report 215, Reference 71-22. Oregon State University, 
    Department of Oceanography. 49 pp.

Bernhardt, H. and A. Wilhelms, 1967. The continuous determination of low level 
    iron, soluble phosphate and total phosphate with the AutoAnalyzer, Technicon 
    Symposia, Volume I, 385-389.

Brewer, P. G. and G. T. F. Wong, 1974. The determination and distribution of 
    iodate in South Atlantic waters. Journal of Marine Research, 32,1:25-36.

Bryden, H. L., 1973. New Polynomials for Thermal Expansion, Adiabatic 
    Temperature Gradient, Deep-Sea Research 20, 401-408.

Bullister, J.L. and R.F. Weiss, 1988. Determination of CCl3F and CCl2F2 in   
    seawater and air. Deep-Sea Research, 35, 839-853.

Carpenter, J. H., 1965. The Chesapeake Bay Institute technique for the Winkler 
    dissolved oxygen method, Limnology and Oceanography 10, 141-143.

Carter, D. J. T., 1980 (Third Edition). Echo-Sounding Correction Tables, 
    Hydrographic Department, Ministry of Defence, Taunton Somerset.

Chen, C.-T. and F. J. Millero, 1977. Speed of sound in seawater at high 
    pressures. Journal Acoustical Society of America, Volume 62, No. 5, 1129-
    1135.

Culberson, C. H., Williams, R. T., et al,August, 1991. A comparison of methods 
    for the determination of dissolved oxygen in seawater, WHP Office Report 
    WHPO 91-2.

Fofonoff, N. P., 1977. Computation of Potential Temperature of Seawater for an 
    Arbitrary Reference Pressure. Deep-Sea Research 24, 489-491.

Fofonoff, N. P. and R. C. Millard, 1983. Algorithms for Computation of 
    Fundamental Properties of Seawater. UNESCO Report No. 44, 15-24.

Hager, S. W., E. L. Atlas, L. D. Gordon, A. W. Mantyla, and P. K. Park, 1972. A 
    comparison at sea of manual and autoanalyzer analyses of phosphate, nitrate, 
    and silicate. Limnology and Oceanography 17 931-937.

Lewis, E. L., 1980. The Practical Salinity Scale 1978 and Its Antecedents. IEEE 
    Journal of Oceanographic Engineering, OE-5, 3-8.

Mantyla, A. W., 1982-1983. Private correspondence.

Millero, F. J., C.-T. Chen, A. Bradshaw and K. Schleicher, 1980. A New High 
    Pressure Equation of State for Seawater. Deep-Sea Research 27A, 255-264.

Saunders, P. M., 1981. Practical Conversion of Pressure to Depth. Journal of 
    Physical Oceanography 11, 573-574.

Sverdrup, H. U., M. W. Johnson, and R. H. Fleming, 1942. The Oceans, Their 
    Physics, Chemistry and General Biology, Prentice-Hall, Inc., Englewood 
    Cliff, N.J.

UNESCO, 1981. Background papers and supporting data on the Practical Salinity 
    Scale, 1978. UNESCO Technical Papers in Marine Science, No. 37, 144 p.

Joyce, T.M. and C. Corry, Ed., 1994, Requirements for WOCE Hydrographic 
    Programme Data Reporting, WHPO 90-1, WOCE Report No. 67/91.

Joyce, T.M., Ed., 1991, WHP Operations and Methods, WHPO 91-1, WOCE Report No. 
    68/91.

Unesco, 1983. International Oceanographic tables. Unesco Technical Papers in 
    Marine Science, No. 44.

Unesco, 1991. Processing of Oceanographic Station Data. Unesco memorgraph By 
    JPOTS editorial panel.



E.  BOTTLE DATA COMMENTS

Remarks for deleted or missing samples from TUNES/WOCE Pacific 91, P17C. 
Investigation of data may include comparison of bottle salinity and oxygen with 
CTD data, review of data plots of station profile and adjoining stations, 
rereading of charts (ie. nutrients). Comments from the Sample Logs and ODF's 
results of investigation are included in this report.


Station 001

122 @ 42db   Sample log: Spring needs tightening. All water 
             samples look good at 42m.

131 @ 293db  Delta-S .010 low at 343db. Calc ok. No notes. 
             All water samples have same value as NB30 at level above. 
             CTDO traces show smoother gradient this area Assume closed 
             at NB30 level (292db). Changed trip file made 31 same trip 
             info as 30. Used 292.7 vs. 343.2 CTD trip data for NB31.

133 @ 443db  Delta-S .050 low at 442db. Calc ok. No notes. 
             Other water samples ok. Same value as NB32 at level above. 
             Assume dupe draw. Footnote salinity uncertain, ODF 
             recommends deletion.
134 @ 492db  Salinity same value as 33 at level above. 
             Assume dupe draw. Footnote salinity uncertain, ODF 
             recommends deletion.
135 @ 519db  Sample log: Leaking from bottom end cap. Delta-
             S .003 high at 519db. Other water samples also look ok.
136 @ 519db  Delta-S .026 low at 550db. Calc ok. No notes. 
             All water samples have same values as NB35 at level above. 
             CTDO salinity and oxygen traces show definite change between 
             NB35 level at 519db and NB36 level. Assume NB36 closed at 
             519db level. Changed trip file made 36 same trip info as 35. 
             Used 518.9 vs. 550.3 CTD trip data for NB36.

STATION 002

113          Bottle was closed but not intended as a sample. NBs 14 
             thru 17 were open as intended and ramp shaft in correct 
             position. Water samples same as NB36 so assume NB 13 closed 
             at first trip. This level is not reported.
129 @ 303db  Sample Log: "Air vent open" Delta-S -0.007 at 
             303db, in line with all other offsets on this station. O2 
             agrees with CTDO.
130 @ 353db  Sample Log: "Air vent open" Delta-S -0.006 at 
             353db, in line with all other offsets on this station. O2 
             agrees with CTDO.

STATION 003

136 @1473db  Sample log: Spigot on deck, bottom end cap 
             lanyard broken. Didn't see what happened. No water samples.

STATION 004

111 @ 77db   Sample log: Stepped on lanyard - let out some 
             water. O2 appears to follow CTDO trace well. Other water 
             samples also ok.
114 @ 149db  Sample log: Leaking out of bottom. Delta-S .03 
             low at 148db. Calc ok. High gradient, down differs from up, 
             CTD temp also bumpy this area. Other water samples look 
             reasonable.
117 @ 298db  Sample log: Leaker. Not specific. Delta-S .000 
             at 297db. Other water samples also ok.
135 @2397db  Sample log: Water valve cracked. Delta-S .000 
             at 2396db. Other samples also okay.

STATION 005

106 @ 143db  Sample log: Closed top late in sampling. Spigot 
             is tight. Spigot difficult to close. Delta-S .032 high at 
             143db. Calc ok. High gradient. Other water samples look ok 
             near CTDO inversion.
109 @ 210db  Sample log: Air vent partially open. Delta-S 
             .02 low at 210 db. Calc ok. Other water also indicate 
             possible leaker but in area of change.
110 @ 261db  Sample log: Air vent partially open. Delta-S 
             .013 low at 261db. Calc ok. Other water samples look ok.
117 @ 605db  Sample log: Air leak. Delta-S .000 at 604db. 
             Other water samples look ok.
118 @ 655db  Delta-S .074 high at 655db. Calc ok. No notes. 
             Other water samples ok. Same value as NB20 2 level deeper. 
             Smooth CTD S trace. Possibly bad draw or bad run. Footnote 
             salinity uncertain, ODF recommends deletion.
121 @ 909db  Bottle oxy appears .1 low at 909db. Calc ok. 
             CTDO trace smooth, although unclear from CTDO whether 121 is 
             low or 119 & 120 are a little high. Footnote o2 uncertain.
128 @2019db  Bottle oxy appears .1 high at 2019db. Calc ok. 
             CTDO trace smooth, footnote o2 uncertain. Delta-S .002 low.
129 @2219db  Sample log: Disc off while sampling. Samples 
             look reasonable. Okay as is.
134 @3251db  Final Delta-S .003 high at 3251db. Calc ok. 
             Smooth CTD gradient. Tsuchiya: "Is this o2 max real? It 
             looks either o2 at 134 is too high or o2 at 135 and 136 is 
             too low." Calc okay, CTDO indicates 135 & 136 too low.
135 @3356db  Bottle oxy appears .1 low. Calc ok. Footnote o2 
             uncertain. CTDO trace has slight jog this way but not .1. 
             Other water samples & CTD traces have smooth gradient. Final 
             Delta-S .005 high at 3356db. Calc ok. Smooth CTD gradient.
136 @3446db  Bottle oxy appears .1 low. Calc ok. Footnote o2 
             uncertain. CTDO trace has slight jog this way but not .1. 
             Other water samples & CTD traces have smooth gradient. Final 
             Delta-S .005 high at 3446db. Found entry error, new hydro 
             salt gives final Delta-S .0027 high.

STATION 006

105 @ 90db   Not sure what happened here. No notes on Sample 
             Log. Samples indicate bottle tripped at ~1200-1450db. Delete 
             salinity, o2, sil, no3, no2, po4, 34.4980 39.7 133.65 42.76 
             0.01 3.05, respectively. Footnote bottle leaking.
107 @ 149db  Sample log: Air vent not completely closed. 
             Delta-S .009 high at 150db. Other water look ok.
109 @ 200db  Sample log: Air vent partially open. Delta-S 
             .005 low at 201 db. Other water samples also ok.
110 @ 226db  Sample log: Air vent partially open. Delta-S 
             .004 at 228 db. Other water samples also ok.
112 @ 297db  Sample log: Bottom cap knocked open. Tsuchiya: 
             "O2 too high?" Delta-S .002 high at 297db. Discrete O2 .7 
             high, calc ok. Nutrients look ok. Footnote oxygen bad. 
             Oxygen seems to be affected by note from sample log, may 
             also have affected other gas samples.
113          Sample log: Moved freon to bottle 22. No water samples. 
             See 134.
114 @ 350db  Changed trip file, scheduled trip 410.
115 @ 399db  Changed trip file, scheduled trip 463.
116 @ 452db  Changed trip file, scheduled trip 509.
117 @ 499db  Sample log: Valve not completely closed. Delta-
             S .001 low at 500db. Other water samples also ok. Changed 
             trip file, scheduled trip 612.
118 @ 603db  Changed trip file, scheduled trip 716.
119 @ 704db  Changed trip file, scheduled trip 820. Delta-S 
             .090 high at 706db. Calc ok. Same value as NB20. Other water 
             samples ok. Assume bad draw or run. Footnote salinity bad, 
             ODF recommends deletion.
120 @ 808db  Changed trip file, scheduled trip 922.
121 @ 909db  Changed trip file, scheduled trip 1024.
122 @1009db  Changed trip file, scheduled trip 1227.
123 @1212db  Changed trip file, scheduled trip 1431.
124 @1414db  Changed trip file, scheduled trip 1636.
125 @1621db  Changed trip file, scheduled trip 1838.
126 @1825db  Changed trip file, scheduled trip 2033.
127 @2018db  Changed trip file, scheduled trip 2237.
128 @2223db  Changed trip file, scheduled trip 2451. Delta-S 
             at 2223db is .004.
129 @2435db  Changed trip file, scheduled trip 2652. Delta-S 
             at 2435db is .0048. Salinity a little noisy for entire 
             trace. Footnote salinity uncertain.
130 @2435db  Delta-S .008 low at 2637.9db. Calc ok. All 
             water samples same as 129 at 2436.4db. Assume trip problem, 
             nothing tripped at 2637.9db and both NBs 29 & 30 tripped at 
             2436.4db. Used 2436.4 vs. 2636.5 CTD trip data for NB30. 
             Changed trip file, scheduled trip 2852. Silicate: Couldn't 
             read peak. Peak very jagged between .990 and 1.000.
131 @2840db  Changed trip file, scheduled trip 3046.
132 @3034db  Delta-S at 3034db is .004. Changed trip file, 
             scheduled trip 3250.
133 @3238db  Changed trip file, scheduled trip 3460.
134 @3451db  Changed trip file, scheduled trip 3673. Delta-S 
             at 3451db is .003. Console Ops Log: "13 still open. No 
             trigger at 34. Delta-Ss on 34 thru 14 give good agreement if 
             all samples moved up one level from intended level.

STATION 007

1sil         Tsuchiya: "Is the increase in sil level in deep layer 
             (>~2000db) from Station 6 to 7 is real." Samples 125- 
             136,Calc appears to be okay, no problems noted.
101 @ 2db    Delta-S 1.9 high at 1db. Calc ok. All water 
             samples indicate bottle closed deep. NO2 unreadable peak, 
             footnote no2 lost. Footnote bottle leaking. Delete salinity, 
             o2, sil, no3, po4, 34.6273 118.6 166.28 38.16 2.65 , 
             respectively.
105 @ 104db  Nutrient: no2 unreadable peak.
108 @ 180db  Sample log: Top was out of frame. Trip rod out 
             of top plate, replaced trip rod later, found broken rod had 
             been used and was too short. Samples look ok.
117 @ 812db  Sample log: Slight air leak. Oxygen looks good. 
             Leave as is.
118 @1006db  Delta-S .02 high at 897db. Calc ok. All water 
             samples indicate bottle closed closer to NB19 at 1005db. 
             Talley: "Footnote salinity as questionable." Salinity sheet 
             notes indicate analyst had to bring in the cast. Delta-S -
             .0112 at 1006 db. Suspect that he was distracted and this 
             salinity is incorrect footnote salinity bad, ODF recommends 
             deletion. Change trip file, scheduled 897.
120 @1006db  Delta-S .02 low at 1110db. Calc ok. All water 
             samples indicate bottle closed at NB19 at 1005db. Change 
             trip file.
129 @2641db  Sample log: Broken in half - destroyed. No 
             samples.
130 @2849db  Sample log: Broken spigot. No samples.
131 @3034db  Delta-S at 3034db is -.005, calc ok. Footnote 
             salinity uncertain. O2 .02 low compared to CTDO, calc ok. 
             Footnote o2 uncertain. Nutrients have more normal gradient.
134 @3555db  Delta-S .007 low at 3821db. Calc ok. Same as 
             133 salt at level above. NO3 & PO4 also same as 133 but Sil 
             & O2 show some gradient. Sil has poor peak that could be 
             interpreted as same as 133. O2 titrated by LTL who had 
             several overtitrations early in the cruise. Suspect tripping 
             problem and NB34 closed at NB33 level. Used 3554db CTD trip 
             data for NB34. Changed trip file made 34 same trip info as 
             33.
136 @4227db  Sample log: Air leak - vent closed - possible 
             bottle crack? Delta-S .002 low at 4226db. Nutrients for 35 & 
             36 lower than other deep bottles but subsequent deep 
             stations show same feature NB 36 ok on subsequent stations. 
             Oxygen okay.

STATION 008

1no3         Tsuchiya: "The lower level (relative to neighboring 
             stations) of NO3 at the NO3 max and below (>~100db) is 
             real?" Calc and peaks okay, no analytical problems noted. 
             Samples 119-136.
101 @ 2db    Sample log: Leaker. Final Delta-S .002 at 2db. 
             Other water samples also look ok.
105 @ 113db  Delta-S .866 high at 113db. All water samples 
             indicate bottle closed deeper, probably about 375db. 
             Footnote bottle leaking. Delete salinity, o2, sil, no3, no2, 
             po4. 34.1821 48.4 85.34 36.82 0.00 2.75, respectively.
109 @ 203db  Sample log: Leaker. Delta-S .004 low at 203db. 
             Other water samples also look ok.
110 @ 249db  Sample log: Leaker. Delta-S .17 high at 249db. 
             Nutrients also appear to be from deeper water. O2 looks ok. 
             Delete salinity, o2, sil, no3, no2, po4, 34.209 2.37 97.5 
             36.4 0.00 2.70, respectively.
112 @ 354db  Delta-S .125 high at 354db. Calc ok. Nutrients 
             also appear to be from deeper water, but O2 looks 
             reasonable. No notes. Footnote bottle leaking. Delete 
             salinity, o2, sil, no3, no2, po4, 34.1991 68.9 90.37 37.92 
             0.00 2.76, respectively.
117 @ 809db  Sample log: Leaking. Delta-S .001 low at 809db. 
             Other water samples also ok.
120 @1012db  Delta-S .053 low at 1215db. Calc ok. All water 
             samples have same value as NB19 at level above. CTDO shows 
             smooth gradient this area. Assume NB20 closed at NB19 
             level(1011db). Changed trip file made 20 same trip info as 
             19. Used 1012.0 vs. 1215.8 CTD trip data for NB20. Tsuchiya: 
             "PO4 looks slightly too high." Calculations and peak okay.
121 @1417db  Tsuchiya: "PO4 looks slightly too high." 
             Calculations and peak okay.
122 @1616db  Sample log: Leaking (bottom seal). Delta-S 1.6 
             low at 1615db. Other water samples also indicate near 
             surface water. Delete salinity, o2, sil, no3, no2, po4, 
             32.9269 248.0 7.73 2.38 0.00 0.61, respectively.
123 @1825db  Tsuchiya: "PO4 looks slightly too high." 
             Calculations and peak okay.
124 @1825db  Delta-S .017 low at 2028db. Calc ok. All water 
             samples have same value as NB23 at level above. CTDO shows 
             smooth gradient this area. Suspect NB24 closed at NB23 
             level(1825db). Changed trip file made 24 same trip info as 
             23. Used 1824.7 vs. 2028.3 CTD trip data for NB24.
126 @2424db  Silicate too high, calc okay, footnote silicate 
             uncertain.
127 @2634db  Sil appears 4 low at 2634db. Calc & peak ok. 
             Footnote sil uncertain.
128 @2634db  Delta-S .006 low at 2842db. Calc ok. All water 
             samples have same value as NB27 at level above. CTDO shows 
             smooth gradient this area. Assume NB28 closed at NB27 
             level(2634db) Changed trip file made 28 same trip info as 
             27. Used 2634.4 vs. 2841.8 CTD trip data for NB28.
130 @3040db  Sample log: Leaking. Delta-S .004 low at 
             3247db. Calc ok. All water samples have same value as NB29 
             at level above. CTDO shows smooth gradient this area. Assume 
             NB30 closed at or near NB29 level(3040db). Changed trip file 
             made 30 same trip info as 29. Used 3039.9 vs. 3247.0 CTD 
             trip data for NB30.
136 @4411db  Delta-S at 4411db is -.003. Looks like 36 
             tripped with 35. No action taken on this, just leave as is.

STATION 009

102 @ 75db   Delta-S .132 high at 37db. Calc ok. All water 
             samples indicate NB2 closed one level below intended level, 
             75db vs 37db. See samples 103 & 104 also. Used CTD trip info 
             at 75db for 102.
103 @ 98db   Delta-S .076 high at 75db. Calc ok. All water 
             samples indicate NB3 closed one level below intended level, 
             98db vs 75db. See samples 102 & 104 also. Used CTD trip info 
             at 98db for 103.
104 @ 126db  Delta-S .303 high at 98db. Calc ok. All water 
             samples indicate NB4 closed one level below intended level, 
             125db vs 98db. See samples 102 & 103 also. Used CTD trip 
             info at 125db for 104.
105 @ 152db  Delta-S 1.03 high at 125db. All water samples 
             appear to be from deeper water. Not consistent with one 
             level. Delete salinity, o2, sil, no3, no2, po4, 34.2898 43.6 
             123.08 41.54 0.01 3.00, respectively. Footnote bottle 
             leaking.
106 @ 176db  Delta-S 1.06 high at 151db. All water samples 
             appear to be from deeper water. Not consistent with one 
             level. Delete salinity, o2, sil, no3, no2, po4, 34.4949 
             102.7 153.71 38.68 0.00 2.73, respectively. Footnote bottle 
             leaking.
107 @ 201db  Delta-S .132 high at 176db. Calc ok. All water 
             samples indicate NB7 closed one level below intended level, 
             201db vs 176db. See samples 102 & 103 also. Used CTD trip 
             info at 201db for 107.
108 @ 250db  Sample log: Dripping through spigot. Delta-S 
             .120 high at 200db. Calc ok. All water samples indicate NB8 
             closed one level below intended level, 250db vs 200db. See 
             samples 102 & 103 also. Final Delta-S .043 low at 250db. 
             Other water samples look ok. Up & Down T&S differ, with 
             hydro S & O2 closer to down trace than up trace. Normal 
             gradient. Used CTD trip info at 250db for 108. Footnote 
             bottle leaking and salinity bad.
109 @ 301db  Sample log: Had broken block and one end cap 
             open. No water samples.
110 @ 353db  Sample log: No spigot. No water samples.
111 @ 401db  Delta-S .014 high at 353db. Calc ok. All water 
             samples look better at level below, 401db vs intended depth. 
             Used NB11 water samples with 401db trip data.
112 @ 1db    ConOps log: "Extra trip on pylon 1 before 
             changing to pylon 2. Delta-S 1.3 low at 400db. Other water 
             samples indicate NB12 closed at surface. All water samples 
             very similar to those from NB1. Used NB 12 water samples 
             with surface trip data.
113-136      Sample log: "Came up open." Console Ops log: "Wire 
             jumped sheave at ~20m, was discovered and put back at 60m." 
             No confirms on outer ring trips. Bad conductor to outer ring 
             pylon. No water samples.

STATION 010

1Deep        Salt-All deep salinities about .002 lower than 
             adjacent stations according to vertical sections and final 
             Delta-Ss. Salinometer data look ok, no drift, standard same 
             as other stations this Autosal. Console ops: new end 
             termination before this cast, also some wire slippage noted 
             by wire out at end of cast. Footnote salinity uncertain. O2-
             Some scatter (.01) on deep hydro O2s. Calc ok. CTDO trace 
             smooth. Footnote o2 uncertain.
101 @ 2db    Sample log: Air leak. Final Delta-S .007 low at 
             1db. Other samples look ok for surface.
105 @ 111db  Delta-S .9 high at 110db. All water samples 
             appear to be from deeper water. Not consistent with one 
             level. Footnote bottle leaking. Delete salinity, o2, sil, 
             no3, no2, po4, 33.9442 25.8 54.17 31.72 0.00 2.24, 
             respectively.
106 @ 136db  Delta-S 1.19 high at 135db. All water samples 
             appear to be from deeper water. Looks like from about 750db. 
             Footnote bottle leaking. Delete salinity, o2, sil, no3, no2, 
             po4, 34.3519 15.9 109.95 43.34 0.00 3.09, respectively.
110 @ 253db  Sample log: valve opened on deck. Delta-S .004 
             low at 253db. Other water samples also look ok.
117 @ 807db  Sample log: Air leaker. Delta-S .000 at 806db. 
             Other water samples also look ok.
120 @1011db  Delta-S .05 low at 1204db. All water samples 
             appear to have tripped at level above, 1010db. Changed trip 
             file made 20 same trip info as 19.
124 @1822db  Delta-S .020 low at 2021db. All water samples 
             appear to have tripped at level above, 1821db. Changed trip 
             file made 24 same trip info as 23.
125 @2226db  See 1Deep comments, footnote salinity and o2 
             uncertain.
126 @2425db  Delta-S at 2425db is -0.004. See 1Deep 
             comments, footnote salinity and o2 uncertain.
127 @2635db  Delta-S at 2635db is -0.006. See 1Deep 
             comments, footnote salinity and o2 uncertain.
128 @2833db  Delta-S at 2833db is -0.003. See 1Deep 
             comments, footnote salinity and o2 uncertain.
129 @3040db  Delta-S at 3040db is -0.006. See 1Deep 
             comments, footnote salinity and o2 uncertain.
130 @3040db  Sample Log: Collar came off while drawing 
             oxygen. Delta-S .007 low at 3288db. All water samples appear 
             to have tripped near level above, 3039db. Changed trip file 
             made 30 same trip info as 29. See 1Deep comments, footnote 
             salinity and o2 uncertain. Delta-S at 3040db is -0.005.
131 @3552db  Sample log: Valve broken off. No water samples
132 @3799db  Sample log: Opened to air on deck. Delta-S .001 
             high at 3799db. Other water samples including O2 ok. See 
             1Deep comments, footnote salinity and o2 uncertain.
133 @4059db  Delta-S at 4059db is -0.004 See 1Deep comments, 
             footnote salinity and o2 uncertain.
134 @4059db  Delta-S at 4322db is -.0068. See 1Deep 
             comments, footnote salinity and o2 uncertain. Sil appears 
             high. Changed trip file made 34 same trip info as 33. Delta-
             S at 4059db is -.0058, and silicate fits station profile 
             much better.
135 @4602db  Delta-S at 4602db is -0.0043 See 1Deep 
             comments, footnote salinity and o2 uncertain.
136 @4766db  Delta-S at 4766db is -0.0047 See 1Deep 
             comments, footnote salinity and o2 uncertain.

STATION 011

1nut         Nutrient: "PO4 will be bad" New tart acid. Nutrients 
             whole run - looks like someone put silicone grease on 
             Niskins!. End Stds off PO4 NO3 use beg f1s for end. System 
             kaput!" PO4 about .15 higher than adjacent stations. NO3 
             about 1.3 higher than adjacent stations. SIL also high. 
             Talley: "Put nutrients back in footnote bad measurement."
1slt         There was a large drift on this salinity run and it 
             looks like the analyst had problems getting two conductivity 
             readings to agree. Footnote salinity uncertain.
101 @ 2db    See 1nut nutrients comment.
102 @ 50db   See 1nut nutrients comment.
103 @ 104db  See 1nut nutrients comment.
104 @ 125db  see 1nut nutrients comment.
105 @ 150db  see 1nut nutrients comment. Delta-S .2 low at 
             150db. Calc ok. High gradient.
106 @ 175db  See 1nut nutrients comment.
107 @ 201db  See 1nut nutrients comment.
108 @ 226db  See 1nut nutrients comment.
109 @ 254db  See 1nut nutrients comment.
110 @ 304db  Sample log: Leaking from bottom end cap - out 
             of water at CO2 Delete high oxygen (166.0 um/kg), obvious 
             bottle leaking problem. Footnote bottle leaking.
111 @ 354db  Delta-S .01 low at 354db. Calc ok. Normal 
             gradient. No notes. See 1nut nutrients comment.
112 @ 402db  See 1nut nutrients comment.
113 @4877db  See 1nut nutrients comment. Delta-S .57 high at 
             505db. Calc ok. Delta-S at 4877db is -.0045. All water 
             samples indicate NB closed near bottom rather than 505db. No 
             water samples from 506db. Used bottom CTD trip data for 
             NB13.
114 @ 603db  Delta-S at 603db is -.0119. See 1nut nutrients 
             comment.
115 @ 708db  See 1nut nutrients comment.
116 @ 811db  Delta-S at 811db is -.0136. See 1nut nutrients 
             comment.
117 @ 909db  See 1nut nutrients comment.
118 @1013db  Delta-S at 1013db is -.0060. See 1nut nutrients 
             comment.
119 @1109db  Delta-S at 1109db is -.0093. See 1nut nutrients 
             comment. See 1slt salinity comment.
120 @1109db  Delta-S .04 low at 1320db. Calc ok. All water 
             samples indicate bottle closed at level above (1108db) with 
             NB 19. Changed trip file made 20 same trip info as 19. Used 
             1108.9 vs. 1311.0 CTD trip data for NB20. See 1nut nutrients 
             comment.
121 @1515db  Delta-S at 1515db is -.0123. See 1nut nutrients 
             comment. See 1slt salinity comment.
122 @1718db  Delta-S at 1718db is -.0130. See 1nut nutrients 
             comment. See 1slt salinity comment.
123 @1922db  Delta-S at 1922db is -.0092. See 1nut nutrients 
             comment. See 1slt salinity comment.
124 @2119db  Delta-S .04 low at 2118db. Calc ok. All water 
             samples indicate NB closed at level above (1921db) with NB 
             23. Oxygen not the same as 23 nor is silicate or salinity, 
             this station had many analysis and tripping problems, but it 
             also appears there were drawing errors. Oxygen would fit 
             better if it came from bottle 23 and vice versa. Leave data 
             at 2119db and footnote samples as uncertain. See 1nut 
             nutrients comment.
125 @2330db  NO2 unreadable peak. See 1nut nutrients 
             comment.
126 @2529db  Delta-S at 2529db is -.0051. See 1nut nutrients 
             comment.
127 @2529db  NO2 unreadable peak. Delta-S at 2529db is -
             .0070, Calc ok. Salt & nutrients same as NB26 from level 
             above. Hydro O2 is .12 lower than NB26 whereas gradient is 
             higher with depth. All bottles lower than 27 also have 
             Delta-S indicating they tripped one level higher than 
             intended. Possibly NB13 closed on 1st trigger, then all 
             bottles closed one level higher than intended up to NB26. 
             NB26 & NB27 closed at the same level (2528db). Cause 
             unknown. No notes re ramp shaft or tripping problems. Used 
             2528db CTD trip data for NB27 as well as NB26. See 1nut 
             nutrients comment.
128 @2740db  Delta-S .012 low at 2935db & .001 low at 
             2740db. See 127 above. Other water samples look reasonable 
             at level above intended level. Used 2740db CTD trip data. 
             See 1nut nutrients comment.
129 @2936db  Sample log: Air leak. Delta-S .010 low at 
             3145db & .002 low at 2936db. See 127 above. Other water 
             samples look reasonable at level above intended level. Used 
             2936db CTD trip data. See 1nut nutrients comment.
130 @2936db  Sample log: Oxygen drawn first. Delta-S .018 
             low at 3400db. Calc ok. All water samples indicate NB closed 
             2 levels above (2936db) with NB 29. NB30 appears to have 
             pylon problem plus problem described in 127 above. See 1nut 
             nutrients comment.
131 @3401db  Delta-S .011 low at 3653db & .002 low at 
             3401db. See 127 above. Hydro O2 is .1 low at 3401db and .1 
             high at 3653db. O2 calc ok. sil looks reasonable at 3653; 
             NO3 & PO4 no good. Used 3401db CTD trip data See 1nut 
             nutrients comment.
132 @3654db  Delta-S .007 low at 3909db & .000 at 3654db. 
             See 127 above. O2 matches CTDO and lower bottle O2s using 
             3543db. Used 3654db CTD trip data See 1nut nutrients 
             comment.
133 @3910db  Delta-S .006 low at 4167db & .000 at 3910db. 
             See 127 above. O2 good at 3543db. Used 3910db CTD trip data 
             See 1nut nutrients comment.
134 @4168db  Delta-S .004 low at 4420db & .002 low at 
             4168db. See 127 above. O2 good @4168db Used 4168db CTD trip 
             data See 1nut nutrients comment.
135 @4421db  Delta-S .003 low at 4683db & .000 at 4421db. 
             See 127 above. O2 good at 4421db. Used 4421db CTD trip data 
             See 1nut nutrients comment.
136 @4684db  Delta-S .015 low at 4876db & .010 low at 
             4684db. See 127 above. O2 good @4684db. Salinity Calc ok. 
             Used 4684db CTD trip data See 1nut nutrients comment.

STATION 012

101 @ 2db    Sample log: Air leak. Delta-S .003 high at 2db. 
             Other water samples are good surface values.
110 @ 313db  Sample log: Bad water leak. O2 not drawn. 
             Delta-S .024 low at 312db. Calc ok. Normal S gradient. 
             Nutrients look ok.
113 @ 608db  Delta-S .09 high at 502db. Calc ok. All data 
             indicate ramp shaft off one place on outer ring and NB35 
             tripped 1st and NB36 tripped last at NB13 intended level. 
             NB13 Delta-S .001 at level below, 608db. Used 608db CTD trip 
             data.
114 @ 709db  Delta-S .08 high at 607db. See 113. Delta-S 
             .003 low at 708db. Used 708db CTD trip data.
115 @ 810db  Delta-S .074 high at 708db. See 113. Used 810db 
             CTD trip data. Delta-S .003 low at 810db.
116 @ 908db  Delta-S .072 high at 810db. See 113. Delta-S 
             .003 low at 908db. Used 908db CTD trip data.
117 @1009db  Delta-S .06 high at 908db. See 113. Delta-S 
             .001 low at 1009db. Used 1009db CTD trip data.
118 @1206db  Delta-S .053 high at 1009db. See 113. Delta-S 
             .001 high at 1206db. Used 1206db CTD trip data.
119 @1415db  Sample log: Petcock pushed in. Delta-S .08 high 
             at 1205db. See 113. Delta-S .000 at 1415db. Other water 
             samples also ok at 1415db Used 1415db CTD trip data.
120 @1415db  Delta-S .002 low at 1415db. Other water samples 
             similar to NB19 and match well at new NB19 level. Assume 
             trip problem as on NB20 other stations before pylon changed, 
             and NB20 triggered at 1616db & closed at 1415db. Oxygen .08 
             too high, footnote oxygen bad analysis. Changed trip file 
             made 20 same trip info as 19.
121 @1817db  Delta-S .02 high at 1615db. See 113. Delta-S 
             .000 at 1817db. Used 1817db CTD trip data.
122 @2020db  Delta-S .016 high at 1817db. See 113 above. 
             Used 2020db CTD trip data. Delta-S at 2020db is -.003.
123 @2223db  Delta-S .012 high at 2020db. See 113. Delta-S 
             .001 low at 2222db. Used 2222db CTD trip data.
124 @2429db  Delta-S .006 high at 2222db. See 113. Delta-S 
             .003 low at 2429db. Used 2429db CTD trip data.
125 @2631db  Delta-S .006 high at 2429db. See 113. Delta-S 
             .002 low at 2631db. Used 2631db CTD trip data.
126 @2838db  Delta-S .004 high at 2631db. See 113. Delta-S 
             .002 low at 2838db. Used 2838db CTD trip data.
127 @3041db  Delta-S .002 high at 2838db. See 113. Delta-S 
             .001 low at 3041db. Used 3041db CTD trip data.
128 @3293db  Delta-S .004 high at 3041db. See 113 above. 
             Delta-S .001 high at 3293db. Used 3293db CTD trip data.
129 @3552db  Delta-S .005 high at 3293db. See 113 above. 
             Delta-S .000 at 3552db. Used 3552db CTD trip data.
130 @3552db  Sample log: Air leak. Delta-S .002 low at 
             3552db. Other water samples similar to NB29 and match well 
             at new NB29 level. Assume trip problem as on NB30 other 
             stations before pylon changed, and NB30 triggered at 3815db 
             & closed at 3552db. Changed trip file made 30 same trip info 
             as 29.
131 @4059db  Delta-S .001 high at 3815db. See 113. Delta-S 
             .000 at 4059db. Used 4059db CTD trip data.
132 @4323db  Delta-S .001 low at 4058db. See 113. Delta-S 
             .001 low at 4322db Used 4322db CTD trip data.
133 @4575db  Delta-S .002 low at 4322db. See 113 above. 
             Delta-S .002 low at 4575db. Used 4575db CTD trip data.
134 @4795db  Delta-S .003 low at 4575db. See 113 above. 
             Delta-S .001 low at 4795db. Used 4795db CTD trip data.
135 @4972db  Delta-S .001 high at 4795db. See 113. Delta-S 
             .002 high at 4972db. Used 4972db CTD trip data.
136 @ 503db  Delta-S .626 low at 4972db. See 113. Delta-S 
             .004 high at 503db. Other water samples match well at 503db. 
             Used 503db CTD trip data.

STATION 013

101-112      Sample log: "did not trip" Sample log: "Package hit 
             bottom" Wire kinked, 12-place pylon electronics bad. No 
             water samples, and no trip information.
105  See 101 comment. Sample log: Bottom end cap closed - 
             tied knot in bottom lanyard.
120 @ 909db  Delta-S .095 low at 1112db. All water samples 
             same as NB19 at level above. Changed trip file made 20 same 
             trip info as 19. Oxygen .06 high, footnote o2 bad analysis.
124 @1717db  Delta-S .021 low at 1919db. All water samples 
             same as NB23 at level above. Changed trip file made 24 same 
             trip info as 23.
128 @2533db  Delta-S .009 low at 2533db. All water samples 
             same as NB27 at level above. Changed trip file made 28 same 
             trip info as 27. Oxygen .08 high, footnote o2 bad.
130 @2941db  Delta-S .007 low at 2941db. All water samples 
             same as NB29 at level above. Changed trip file made 30 same 
             trip info as 29. Oxygen .02 high, footnote o2 bad.
131 @3154db  Delta-S .004 low at 3358db. All water samples 
             appear to be from level above (3154db, NB30 intended level). 
             Delta-S .001 high at 3154db.
135 @4253db  Hydro o2 appears .05 high at 4253db compared to 
             CTDO trace. Calc ok. Footnote oxygen uncertain. Delta-S .003 
             high at 4253db. Nutrients look ok.
136 @4469db  Hydro o2 appears .05 low at 4469db compared to 
             adjacent stations but looks ok compared to CTDO trace. See 
             135 above. Other water samples look ok. Footnote oxygen 
             uncertain.

STATION 014

1slt         Salinity analyst had problems getting the 
             conductivities to agree, specifically bottles 
             2,13,15,17,24,25,27,36. Samples 116 thru 123, 796 to 2055db, 
             all have low hydro salinities(.011 to .018). Deeper hydro 
             salts 128 thru 136 are also low(.002 to .009). Autosal run 
             looks ok, no drift, std dial, SBY no. & air temp ok, 
             footnote salinity bad.
101 @ 3db    Sample log: "Air Leaker" Delta-S .005 low at 3db. 
             Other water samples ok at surface.
107 @ 138db  Sample log: "nipple broken on retrieval but no 
             water leak. Sample log: salt, nutrient & C14 drawn only." 
             Delta-S .011 low at 138db. Calc ok. High gradient.
110 @ 232db  Sample log: "air leak again" Delta-S .010 high 
             at 232db. High gradient, inversion. Other water samples ok, 
             o2 minimum.
113 @5225db  Delta-S .63 high at 502db. Calc ok. All water 
             samples appear to be from bottom. Delta-S at bottom level, 
             5225db is .010 low. o2 & nuts same as NB36. Changed trip 
             file made 13 same trip info as 36.
116 @ 797db  Delta-S .018 low at 796db. Calc ok. Normal 
             gradient. See 1slt comment, footnote salinity bad.
117 @ 901db  Sample log: "vent cock leak" Delta-S .018 low 
             at 901db. Calc ok. Normal gradient. See 1slt comment, 
             footnote salinity bad. Other water samples ok.
118 @ 994db  Delta-S .012 low at 994db. Calc ok. Normal 
             gradient. See 1slt comment, footnote salinity bad.
119 @1203db  Delta-S .011 low at 1203db. Calc ok. Normal 
             gradient. See 1slt comment, footnote salinity bad.
120 @1203db  Delta-S .051 low at 1400db. All water samples 
             same as NB19 at level above. See 1slt comment, footnote 
             salinity bad. Changed trip file made 20 same trip info as 
             19.
121 @1611db  Delta-S .016 low at 1610db. Calc ok. Normal 
             gradient. See 1slt comment, footnote salinity bad. Tsuchiya: 
             "Sil too high in comparison with adjoining stations." Calc 
             okay, peaks fair.
122 @1807db  Sample log: "cap off plug" Don't know what this 
             means. Delta-S .018 low at 1807db. Calc ok. Normal gradient. 
             See 1slt comment, footnote salinity bad. Other water samples 
             ok. Tsuchiya: "Sil too high in comparison with adjoining 
             stations." Calc okay, peaks fair.
123 @2054db  Delta-S .013 low at 2054db. Calc ok. Normal 
             gradient. See 1slt comment, footnote salinity bad. Tsuchiya: 
             "Sil too high in comparison with adjoining stations." Calc 
             okay, peaks fair.
124 @2054db  Delta-S .027 low at 2054db. All water samples 
             same as NB23 at level above. Changed trip file made 24 same 
             trip info as 23. See 1slt comment, footnote salinity bad.
127 @2919db  Sample log: "air leak. Not fully closed on top 
             when brought on board. Found top lanyard from 26 in end cap 
             27 prior Sta 15." Delete salinity, o2, sil, no3, no2, po4, 
             34.6423 106.6 173.71 39.46 0.03 2.74, respectively.
128 @3185db  Delta-S .007 low at 3185db. Calc ok. See 116 
             above. Final CTD deep ts has good agreement with adjacent 
             stations. See 1slt comment, footnote salinity bad.
129 @3439db  Delta-S .005 low at 3439db. Calc ok. See 128 
             above. See 1slt comment, footnote salinity bad.
130 @3439db  Sample log: "air leak" Delta-S .013 low at 
             3701db. All water samples same as NB29 at level above. See 
             1slt comment, footnote salinity bad. Changed trip file made 
             30 same trip info as 29.
131 @3702db  Delta-S .009 low at 3960db. Calc ok. See 128 
             above. All water samples indicate slight leak or late close. 
             Changed trip file made 31 same trip info as expected trip of 
             30 (~3700db). See 1slt comment, footnote salinity bad.
132 @4212db  Delta-S .005 low at 4212db. Calc ok. See 128 
             above. See 1slt comment, footnote salinity bad.
133 @4578db  Delta-S .007 low at 4578db. Calc ok. See 128 
             above. See 1slt comment, footnote salinity bad.
134 @4578db  Delta-S .014 low at 4734db. All water samples 
             same as NB33 at level above. See 1slt comment, footnote 
             salinity bad. Changed trip file made 34 same trip info as 
             33.
135 @4998db  Delta-S .003 low at 4998db. Calc ok. See 128 
             above. See 1slt comment, footnote salinity bad.
136 @5225db  Delta-S .004 low at 5225db. Calc ok. See 128 
             above. See 1slt comment, footnote salinity bad.

STATION 015

109 @ 270db  Sample log: "bottom end cap hung up - no water"
113          Sample log: "No trip" No water samples. No confirm at 
             NB15 intended level at 827db (o2 min) so assumed no samples 
             at 827db and NBs 15&14 each tripped at level above intended 
             level. Computer trip info confirms.
114 @ 606db  Changed trip file, scheduled trip 720.
115 @ 709db  Changed trip file, scheduled trip 827.
120 @1316db  Delta-S .038 low at 1511db. All water samples 
             indicate NB20 closed at level above. Changed trip file made 
             20 same trip info as 19.
122 @1920db  Sample log: "Stop cock off @ oxy" Means spigot 
             disk came off before o2 drawn. Water samples look ok.
124 @2126db  Delta-S .015 low at 2332db. All water samples 
             indicate NB24 closed at level above. Changed trip file made 
             24 same trip info as 23.
129 @3450db  Sample log: "Air Leak - vent not tight." Delta-
             S .002 high at 3450db. Other water samples ok.
130 @3450db  Delta-S .007 low at 3706db. All water samples 
             indicate NB30 closed at level above. Changed trip file made 
             30 same trip info as 29.
131 @3963db  Hydro o2 .1 low at 3963db. Calc ok. Smooth CTDO 
             trace, footnote o2 uncertain.
133 @4477db  Hydro o2 .05 high at 4477db. Calc ok. Smooth 
             CTDO trace, footnote o2 uncertain.
136 @5189db  Sample log: "Air Leak" Delta-S .000 at 5189db. 
             Other water samples also ok.

STATION 016

102 @ 58db   Sample log: "Slow air leak" Delta-S .008 at 
             58db. Other water samples also ok.
105 @ 120db  Sample log:"Small air leak, top not set well" 
             Delta-S .064 low at 120db. Calc ok.
108 @ 209db  Sample log:"Tag is missing" Don't know what 
             this means. Delta-S .013 high at 209db. Calc ok. Other water 
             samples ok.
109 @ 230db  Sample log:"Bottom end piece caught on 
             altimeter - No sample."
110 @ 256db  Sample log:"Small air leak" Delta-S .001 high 
             at 256db. Other water samples also ok.
117 @ 704db  Sample log:"Slow air leak" Delta-S .002 low at 
             704db. Other water samples also ok.
119 @ 913db  Tsuchiya: "PO4 too low." Poor peaks, calc okay, 
             footnote po4 bad. Talley: "PO4 all too low, 19-35, 36 okay." 
             Footnote po4 bad.
120 @1007db  Footnote po4 bad, per 119 Talley's request.
121 @1210db  Footnote po4 bad, per 119 Talley's request.
122 @1412db  Footnote po4 bad, per 119 Talley's request.
123 @1616db  Footnote po4 bad, per 119 Talley's request.
124 @1819db  Footnote po4 bad, per 119 Talley's request.
125 @2023db  Sample log:"opened, to remove lanyard, on 
             deck"See 127 below. Delta-S .002 low at 2022db. PO4 about 
             .03 high but other water samples look ok. Delete salinity, 
             o2, sil, no3, no2, po4, 34.6037 72.3 168.47 41.02 0.00 2.87, 
             respectively.
126 @2227db  Footnote po4 bad, per 119 Talley's request.
127 @2430db  Sample log:"open-lanyard caught in top of 25" 
             No water samples.
128 @2634db  Footnote po4 bad, per 119 Talley's request.
129 @2833db  Delta-S at 2833db is -.0034. Footnote po4 bad, 
             per 119 Talley's request.
130 @2833db  Sample log:"air leak" Delta-S .006 low at 
             3042db. All water samples same as NB29 at level above. 
             Footnote po4 bad, per 119 Talley's request.
131 @3042db  Delta-S .004 low at 3244db, and Delta-S .000 at 
             level above (3042db). Other water samples have smoother 
             gradient using 3042db trip data for NB31. Used 3042db CTD 
             trip data for NB31. Assumed no samples at 3245db. Footnote 
             po4 bad, per 119 Talley's request.
132 @3449db  Footnote po4 bad, per 119 Talley's request.
133 @3658db  Delta-S at 3658db is -.0039. Salinity a little 
             low compared with CTD, footnote salinity uncertain. Footnote 
             po4 bad, per 119 Talley's request.
134 @3856db  Footnote po4 bad, per 119 Talley's request.
135 @4084db  Footnote po4 bad, per 119 Talley's request.
136 @4409db  Tsuchiya: "PO4 and NO3 too high (downward 
             increases seem doubtful)" PO4 appears .05 high at 4409db. 
             Orig had bad peak. Used rerun after standards, footnote po4 
             bad. NO3 peaks okay. Talley: "po4 okay."

STATION 017

201 @ 1db    Sample log:"Slow leak"."Spigot ring off" Delta-S 
             .003 high at 1db. Other water samples also ok.
202 @ 53db   Sample log: "Slight air leak - top cap" Delta-S 
             .003 low at 53db. Other water samples also look ok.
217 @ 907db  Sample log: "Slow leak" Delta-S .004 low at 
             907db. Other water samples also ok.
220 @1212db  Delta-S .042 low at 1413db. All water samples 
             indicate NB20 closed at level above (1212db). Changed trip 
             file made 20 same trip info as 19.
227 @3041db  Sample log: "Empty" Bottom lanyard snap hook 
             hung up on top lanyard. No water samples.
230 @3552db  Sample log: "Air leak and spigot washer came 
             off." Delta-S .005 low at 3807db. All water samples indicate 
             NB30 Closed at level above (3552db). Changed trip file made 
             30 same trip info as 29.
231 @3808db  Hydro o2 about .1 low at 4068db. Calc ok. 
             Nutrients high, also indicating sample is from higher in 
             water column. Delta-S .000 but very small salinity gradient. 
             Assuming NB31 closed at intended NB30 level (see 230 above), 
             o2 in good agreement with CTDO and nutrients have smoother 
             profile. Delta-S at higher level is .001 high. Used 3808db 
             CTD trip data for NB31.
232 @4068db  Hydro o2 about .1 low at 4323db. Calc ok. 
             Nutrients high, also indicating sample is from higher in 
             water column. Delta-S .001 but very small salinity gradient. 
             Assuming NB32 closed at intended NB31 level (see 231 above), 
             o2 in good agreement with CTDO and nutrients have smoother 
             profile. Delta-S at higher level is .002 high. Used 4068db 
             CTD trip data for NB32.
233 @4578db  PO4 .03 high at 4578db. Calc ok. Original peak 
             was bad and rerun used, footnote po4 bad.
235 @5103db  Delta-S .003 high at 5103db. Calc ok. No notes. 
             CTD trace shows S increase below 235 whereas hydro S 
             decreases. Possible salt sample mix-up between NB 35 & NB 
             36. Footnote salinity uncertain.
236 @5222db  Delta-S .0042 low at 5222db. Calc ok. No notes. 
             CTD trace shows S increase below 235 whereas hydro S 
             decreases. Possible salt sample mix-up between NB 35 & NB 
             36. Footnote salinity uncertain.

STATION 018

101 @ 2db    Sample log:"Air leak" Final Delta-S .005 high at 
             2db. Other water samples ok.
112 @ 402db  Sample log:"Pet cock valve open" Final Delta-S 
             .005 high at 402db. Other water samples ok.
113 @5189db  Delta-S .680 high at 504db. All water samples 
             appear to be from bottom of water column at NB36 level. 
             Changed trip file made 13 same trip info as 36. Talley: 
             "Silicate looks a little high, 22,23,25,26 33,34,35,36,13, 
             maybe not enough to worry about." Footnote sil uncertain.
117 @ 905db  Sample log:"Air leak, pet cock" Delta-S .001 
             high at 905db. Other water samples also ok.
119 @1211db  Sample log:"Possible head space, water came out 
             bottom when rosette was landed." Delta-S .002 low at 1211db. 
             Other water samples also ok.
120 @1211db  Delta-S .054 low at 1413db. All water samples 
             same as NB19 at level above. Changed trip file made 20 same 
             trip info as 19.
121 @1414db  Delta-S .038 low at 1616db. All water samples 
             appear to be from intended NB20 level above (1414db). Delta-
             S at 1414db is .003 high, hydro o2 agrees with CTDO, and 
             nutrients have smooth gradient. Use 1414db CTD trip data for 
             NB21. 910610/dm
122 @1825db  Talley: "Silicate looks a little high, 
             22,23,25,26 33,34,35,36,13, maybe not enough to worry 
             about." Footnote sil uncertain.
123 @2028db  Delta-S at 2028db is .0034. Talley: "Silicate 
             looks a little high, 22,23,25,26 33,34,35,36,13, maybe not 
             enough to worry about." Footnote sil uncertain.
124 @2227db  Sample log:"Bottom end cap open, metal crimp 
             sleave caught on snap hook." No water samples.
125 @2428db  Delta-S at 2428db is .0045. Talley: "Silicate 
             looks a little high, 22,23,25,26 33,34,35,36,13, maybe not 
             enough to worry about." Footnote sil uncertain.
126 @2637db  Talley: "Silicate looks a little high, 
             22,23,25,26 33,34,35,36,13, maybe not enough to worry 
             about." Footnote sil uncertain.
127 @2841db  Sample log:"Lanyard from Bottle 28 caught in 
             top of 27" Samples contaminated. Delete salinity, o2, sil, 
             no3, no2, po4, 34.6248 88.5 171.70 39.94 0.01 2.81, 
             respectively.
130 @3352db  Delta-S .005 low at 3602db. All water samples 
             same as level above except oxygen. Changed trip file made 30 
             same trip info as 29. Oxygen low compared with CTDO and 
             duplicate sample. Footnote oxygen bad. Scheduled trip 
             3602db.
133 @4371db  Talley: "Silicate looks a little high, 
             22,23,25,26 33,34,35,36,13, maybe not enough to worry 
             about." Footnote sil uncertain.
134 @4623db  Talley: "Silicate looks a little high, 
             22,23,25,26 33,34,35,36,13, maybe not enough to worry 
             about." Footnote sil uncertain.
135 @4962db  sil appears a little low (or 136 sil is high). 
             Calc ok, but poor peaks, footnote sil uncertain.
136 @5189db  sil appears a little high(or 135 sil is low). 
             Calc ok, but poor peaks, footnote sil uncertain.

STATION 019

101 @ 2db    Sample log: "Air leak" Delta-S .000 at 2db. Other 
             water sample also ok.
120 @1210db  Delta-S .052 low at 1414db. All water samples 
             same as NB19 at level above. Changed trip file made 20 same 
             trip info as 19. Oxygen a little high, footnote o2 
             uncertain.
121 @1415db  Delta-S .035 low at 1619db. All water samples 
             look good at level above, intended NB20 level. Final Delta-S 
             at 1415db is .000. Use CTD trip data at 1415db for NB21 
             samples. 920611/dm
124 @2021db  Delta-S .017 low at 2226db. All water samples 
             same at NB23 at level above. Changed trip file made 24 same 
             trip info as 23.
125 @2435db  Tsuchiya: "Salinity seems low by ~.003 than 
             neighboring stations." Calculations okay, leave as is.
126 @2637db  Tsuchiya: "Salinity seems low by ~.003 than 
             neighboring stations." Calculations okay, leave as is.
127 @2844db  Tsuchiya: "Salinity seems low by ~.003 than 
             neighboring stations." Calculations okay, leave as is.
128 @3097db  Tsuchiya: "Salinity seems low by ~.003 than 
             neighboring stations." Calculations okay, leave as is.
129 @3354db  Tsuchiya: "Salinity seems low by ~.003 than 
             neighboring stations." Calculations okay, leave as is.
130 @3354db  Delta-S .006 low at 3605db. All water samples 
             same as NB29 at level above.
131 @3606db  Delta-S .005 low at 3859db. All water samples 
             indicate leak or late close. Changed trip file made 31 same 
             trip info as 30.
113 @5134db  Delta-S .685 high at 503db. All water samples 
             same as bottom bottle (NB36 at 5134db). Changed trip file 
             made 13 same trip info as 36.
136 @5134db  Either this bottle or 13 leaked or had a late 
             closure. Since 13 is footnoted, leave this as is.

STATION 020

103 @ 117db  Sample log:"Did not close" No water samples.
106 @ 175db  Sample log: Nipple not full out. Samples appear 
             to be okay.
120 @1009db  Delta-S .07 low at 1206db. All water samples 
             same as NB19 at level above. Changed trip file made 20 same 
             trip info as 19.
130 @3046db  Delta-S .008 low at 3296db. All water samples 
             same as NB29 at level above. Sample log: Air leak. Samples 
             appear to be okay @3045db. Changed trip file made 30 same 
             trip info as 29.
131 @3297db  Delta-S .007 low at 3560db. All water samples 
             fit well at level above (intended NB30 level). Final Delta-S 
             at 3297db is .005 high but agrees with adjacent Delta-Ss. 
             See 132 below. Use CTD trip data at 3297db for NB31 water 
             samples.
134 @4086db  Hydro o2 appears .1 low at 4327db. All water 
             samples same as NB33 at level above but CTD indicates no 
             gradient in salinity. Delta-S .000. Nutrients do have 
             gradient and indicate mistrip. Changed trip file made 34 
             same trip info as 33.

STATION 021

101 @ 2db    Sample log:"Leaking water from nipple - air leak 
             - nipple was partly open." Delta-S .004 at 2db. Other water 
             samples look ok. This is only sample in mixed layer.
117 @ 711db  Hydro o2 about .1 high at 711db compared to 
             adjacent stations. Calc ok. No notes, footnote o2 uncertain. 
             Other water samples ok.
118 @ 809db  Hydro o2 about .1 high at 809db compared to 
             adjacent stations. Calc ok. No notes, footnote o2 uncertain. 
             Other water samples ok.
126 @2230db  Hydro o2 about .1 high @2230db compared to 
             adjacent stations. Calc ok. No notes, footnote o2 uncertain. 
             Other water samples ok. Delta-S at 2230db is .0041.
128 @2637db  Hydro o2 about .1 high at 2637db compared to 
             adjacent stations. Calc ok. No notes. Other water samples 
             ok, footnote o2 uncertain.
129 @2836db  Hydro o2 about .1 high at 809db compared to 
             adjacent stations. Calc ok. No notes, footnote o2 uncertain. 
             Other water samples ok.
130 @3045db  Sample log:"Air leak" Delta-S .001 high at 
             3045db. Hydro o2 about .1 high compared to adjacent 
             stations. Calc ok. No notes. Other water samples ok. 
             Duplicate trip only .003 lower, so these samples probably 
             okay.
131 @3045db  Delta-S .002 low at 3139db. All water samples 
             same as NB30 at level above. Assume tripping problem. 
             Changed trip file made 31 same trip info as 30.
132 @3454db  o2 .1 high at 3454db compared to CTDO & 
             adjacent stations. Calc ok. No notes, footnote o2 uncertain. 
             Other water samples ok. Delta-S at 3454db is .0035.
134 @3657db  Delta-S .003 low at 3856db. All water samples 
             same as NB33 at level above. Assume tripping problem. 
             Changed trip file made 34 same trip info as 33.
135 @4052db  o2 .1 high at 4052db compared to CTDO & 
             adjacent stations. Calc ok. No notes, footnote o2 uncertain. 
             Other water samples ok.

STATION 022

101 @ 1db    Sample log: "Air leak" Surface sample appears okay.
107 @ 197db  Sample log: "Loose air vent" Delta-S .002 low 
             at 197db. Other water samples also ok.
123 @2023db  Delta-S .004 low at 2023db. Calc ok. Other 
             water samples ok Normal CTD gradient. No notes. Footnote 
             uncertain, it is just not within the accuracy of the 
             measurement, but just to let users realize there may be a 
             problem.
129 @3296db  Duplicate trip with 130, Oxygen seems .02 high 
             compared with CTD profile. Footnote o2 uncertain.
130 @3296db  Sample log: "Slight air leak" Delta-S .004 low 
             at 3552db. All water samples same as NB29 at level above. 
             Oxygen fit the CTD profile, 129 seems .02 high. Changed trip 
             file made 30 same trip info as 29.
131 @3553db  Delta-S .004 low at 3805db. All bottle samples 
             have break in gradient at 3805db whereas CTD has smooth 
             traces. Bottle samples appear to fit much better at intended 
             NB30 level (3553db). Use 3553db CTD trip data for NB31 and 
             no water samples at 3805db.
134 @4578db  Hydro o2 .03 low at 4578db. Calc ok. Delta-S 
             .001 low & other water samples also ok. No notes, footnote 
             o2 uncertain.

STATION 023

101 @ 1db    Sample log:"Slight air leak" Delta-S .001 at 1db. 
             Other water samples also ok.
130 @3451db  Sample log: "Slight air leak" Delta-S .000 at 
             3451db. Other water samples also ok.
131 @3451db  Delta-S .004 low at 3657db. All water samples 
             same as NB30 at level above. Changed trip file made 31 same 
             trip info as 30.
134 @4268db  o2 .04 low at 4268db. Calc ok. Delta-S .000 but 
             salts and nutrients have essentially no gradient at bottom. 
             CTD o2 sensor not working this cast. o2 is same as NB33 
             above so possibly NB34 tripped at NB33 level. Sil is 
             slightly high, no3 slightly high. Footnote sil and no3 
             uncertain.

STATION 024

104 @2636db  Tsuchiya: "O2 looks too high." Calc okay, no 
             notes other water samples okay. Footnote o2 uncertain.

STATION 025

1slt         Sample log: Box O left in rosette room - four bottles 
             36-33 drawn. Box Z - redraw 36-33 then continue. The 
             salinity samples 133-136 were mistakenly thrown out before 
             they were analyzed.
101 @ 1db    Sample log: "Air leak" Delta-S .003 high at 1db. 
             Other water sample also ok.
133 @4435db  Sample log: "Bottom 4 smpls lost when used for 
             Sta 26- 2: salt box left in ros rm ~12 hours." No hydro 
             salinity. Console Ops: "Confirms every other trip, ISI gets 
             multiple level each trip. Data indicate all triggers are 
             tripping whether they confirm or not. NB33 tripped at same 
             level as NB34. Oxygen .033 ml/l low. Footnote o2 uncertain.
134 @4431db  Sample log: "Bottom 4 smpls lost when used for 
             Sta 26- 2: salt box left in ros rm ~12 hours." No hydro 
             salinity.
135 @4656db  Sample log: "Bottom 4 smpls lost when used for 
             Sta 26- 2: salt box left in ros rm ~12 hours." No hydro 
             salinity. "Water leak out of bottom cap when air valve 
             opened." Console Ops: "Confirms every other trip, ISI gets 
             multiple level each trip. Data indicate all triggers are 
             tripping whether they confirm or not. NB35 tripped at same 
             level as NB36. No Delta-S, other water samples look ok.
136 @4658db  Sample log: "Bottom 4 smpls lost when used for 
             Sta 26- 2: salt box left in ros rm ~12 hours." No hydro 
             salinity.

STATION 026

2nut         Nutrients: Too much CO2 in SW. PO4 bubbles get too 
             big, get sucked into flow cell. Suspect the problem was in 
             the line, since all 4 channels indicate a problem.
2sil         Sil peaks uncertain 23-36, and reruns of many samples 
             did not give any better results. Sil 23-36 3.+ too high, 
             footnote sil bad or lost if peaks could not be obtained.
217 @1016db  PO4 high, footnote bad, see 2nut comment.
218 @1213db  Sample log: Oxygen stopper fell - rerinsed. 
             Oxygen fits station profile and CTDO. Nutrients: Too much 
             CO2 in SW. No po4 peak read.
219 @1413db  Nutrients: Too much CO2 in SW. No po4 peak 
             read.
220 @1621db  PO4 high, footnote bad, see 2nut comment.
221 @1827db  PO4 high, footnote bad, see 2nut comment.
222 @2029db  PO4 high, footnote bad, see 2nut comment. 
             Oxygen high, footnote uncertain, compared to CTDO and 
             adjoining stations.
223 @2231db  Nutrients: Too much CO2 in SW. No po4 peak 
             read. See 2sil comments, footnote sil bad.
224 @2432db  Nutrients: Too much CO2 in SW. No po4 peak 
             read, no sil peak read.
225 @2642db  Nutrients: Too much CO2 in SW. No po4 peak 
             read. See 2sil comments, footnote sil bad.
226 @2841db  Nutrients: Too much CO2 in SW. No po4 peak 
             read. See 2sil comments, footnote sil bad.
227 @3041db  Nutrients: Too much CO2 in SW. See 2sil 
             comments, footnote sil bad.
228 @3297db  See 2sil comments, footnote sil bad.
229 @3548db  Nutrients: Too much CO2 in SW. No po4 peak 
             read, no sil peak read.
230 @3704db  PO4 high, footnote bad, see 2nut comment. See 
             2sil comments, footnote sil bad.
231 @4054db  See 2sil comments, footnote sil bad.
232 @4312db  See 2sil comments, footnote sil bad.
233 @4577db  See 2sil comments, footnote sil bad.
234 @4814db  See 2sil comments, footnote sil bad.
235 @5081db  See 2sil comments, footnote sil bad.
236 @5271db  Sample log: Leaky before vent. Oxygen high, 
             footnote o2 bad, compared to CTDO. Footnote bottle leaking 
             to caution shorebased users. Appears that leak effected gas 
             sample. See 2sil comments, footnote sil bad.

STATION 027

101 @ 1db    Sample log: Loose air vent. Samples appear to be 
             okay.
115 @ 510db  NO2 peak very "glitchy" and jumped to .65+, 
             unreadable peak.
116 @ 607db  NO2 peak very "glitchy" and jumped to .65+, 
             unreadable peak.
127 @2432db  Tsuchiya: "PO4 too high." Calc okay, reruns, 
             poor peaks, which indicates some contamination in the 
             sample. Footnote po4 bad.
128 @2632db  Tsuchiya: "PO4 too high." Calc okay, reruns, 
             poor peaks, which indicates some contamination in the 
             sample. Footnote po4 bad.
129 @2833db  Tsuchiya: "PO4 too high." Calc okay, reruns, 
             poor peaks, which indicates some contamination in the 
             sample. Footnote po4 bad.
130 @3036db  PO4 peak very "glitchy" , unreadable peak.
133 @3803db  PO4 peak very "glitchy", unreadable peak.

STATION 028

101 @ 2db    Sample log: Air leak. Oxygen agrees with adjacent 
             stations.
108 @ 233db  NO2 unreadable peak, see 1nut comments.
110 @ 294db  NO2 unreadable peak, see 1nut comments.
111 @ 334db  NO2 unreadable peak, see 1nut comments.
112 @ 393db  NO2 unreadable peak, see 1nut comments.
113 @ 455db  NO2 unreadable peak, see 1nut comments.
114 @ 505db  NO2 unreadable peak, see 1nut comments.
115 @ 557db  NO2 unreadable peak, see 1nut comments.
116 @ 628db  NO2 unreadable peak, see 1nut comments.
117 @ 708db  NO2 unreadable peak, see 1nut comments.
126 @2230db  NO2 unreadable peak, see 1nut comments.
127 @2427db  NO2 unreadable peak, see 1nut comments.
128 @2634db  NO2 unreadable peak, see 1nut comments.
129 @2836db  NO2 unreadable peak, see 1nut comments.
133 @3834db  NO2 unreadable peak, see 1nut comments.
134 @4068db  NO2 unreadable peak, see 1nut comments.
136 @4564db  PO4 spiky, unreadable peak.

STATION 029

101 @ 2db    Sample log: Air leak. Sample log: Top knocked 
             during removal c/o w. Samples agree with adjacent stations, 
             so okay for surface sample.
120 @1316db  Sample log: Needs new snap hook. Samples appear 
             to be okay.
135 @3659db  Sample log: Need inner lanyards tightened. 
             Samples appear to be okay.

STATION 030

1nut         Tsuchiya: "Deep NO3 looks too high." Tsuchiya: "Deep 
             SiO3 higher than adjoining stations." Nutrients: End no3 DDW 
             SW Screwy. High drift no2 Cleaned system. Repeak no3, po4. 
             New no2 draw tube. New photo tube no3 (????) Silicate 
             appears high from about 1500m down. Trace is close to 026-
             02. Calc okay, peaks fair. Footnote sil uncertain 123-136.
107 @ 176db  Sample log: Air leak. Delta-S at 176db is -
             .0729. Other samples look reasonable.
111 @ 304db  Tsuchiya: "PO4 and NO3 too high." Calc and 
             peaks okay.
112 @ 356db  Delta-S at 356db is .1319. Analyst indicated 
             radio interference. Could have occurred on this sample 
             though not specifically noted. Sample log: Air valve and 
             spigot open. Oxygen ~.18 ml/l high. Salinity is way out of 
             line. Delete salinity, o2, sil, no3, no2, po4, 34.1596 175.8 
             30.01 20.37 0.01 1.46, respectively. Footnote bottle 
             leaking.
116 @ 604db  Talley: "Footnote silicate as uncertain since 
             these are also quite high." Sil high, See 1nut comments, 
             footnote sil uncertain.
117 @ 713db  Talley: "Footnote silicate as uncertain since 
             these are also quite high." Sil high, See 1nut comments, 
             footnote sil uncertain.
118 @ 810db  Talley: "Footnote silicate as uncertain since 
             these are also quite high." Sil high, See 1nut comments, 
             footnote sil uncertain.
119 @ 913db  Talley: "Footnote silicate as uncertain since 
             these are also quite high." Sil high, See 1nut comments, 
             footnote sil uncertain.
120 @1011db  Talley: "Footnote silicate as uncertain since 
             these are also quite high." Sil high, See 1nut comments, 
             footnote sil uncertain. NO3 high, see 1nut, calc okay, 
             footnote no3 uncertain.
121 @1210db  Talley: "Footnote silicate as uncertain since 
             these are also quite high." Sil high, See 1nut comments, 
             footnote sil uncertain. NO3 high, see 1nut, calc okay, 
             footnote no3 uncertain.
122 @1416db  Talley: "Footnote silicate as uncertain since 
             these are also quite high." Sample log: Broken lanyard. 
             Samples look reasonable. NO3 high, see 1nut, calc okay, 
             footnote no3 uncertain. Sil high, See 1nut comments, 
             footnote sil uncertain.
123 @1618db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
124 @1823db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
125 @2030db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
126 @2231db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
127 @2431db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
128 @2632db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
129 @2832db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
130 @3039db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
131 @3248db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
132 @3449db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
133 @3658db  NO3 low compared with other high values, see 
             1nut, calc okay, footnote no3 uncertain. Sil high, See 1nut 
             comments, footnote sil uncertain.
134 @3858db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
135 @4128db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.
136 @4392db  NO3 high, see 1nut, calc okay, footnote no3 
             uncertain. Sil high, See 1nut comments, footnote sil 
             uncertain.

STATION 031

104 @ 141db  Delta-S at 141db is -.0495. Salinity appears 
             low compared to adjacent stations. No analysis problems 
             noted, footnote salinity uncertain. Other samples appear to 
             be okay.
106 @ 191db  Delta-S .07 low at 191db. Calc ok. All water 
             samples appear to be from about 300db. No notes. Footnote 
             bottle leaking for other sample investigators. Delete 
             salinity, o2, sil, no3, no2, po4, 34.0328 169.7 29.81 20.58 
             0.00 1.47, respectively.
113 @ 443db  Tsuchiya: "O2 too high." Calc okay, CTDO 
             inversion, leave for now.
115 @ 556db  Sample log: Spigots broken off on side of ship 
             - no water.
116 @ 607db  Sample log: Spigots broken off on side of ship 
             - no water.
118 @ 811db  NO2 unreadable peak.
128 @2626db  NO2 unreadable peak.
134 @4068db  Nutrients: Samples mistakenly missed.

STATION 032

115 @ 641db  Silicate appears a little high, footnote sil 
             uncertain.
116 @ 704db  Sample log: Drip at spigot with air vent open. 
             Samples appear to be okay.

STATION 034

206 @3297db  Sample log: Top cracked open on removal - no 
             leaks. Oxygen water temp. +-.4. First check was 6.4? Second 
             check was 5.9 after sampling. Oxygen slightly high, suspect 
             there was an air leak. Footnote bottle leaking, o2 bad.
207 @3554db  Sample log: Top cracked open on removal - no 
             leaks. Samples appear to be okay.
210 @4276db  Not sure what happened, but oxygen unreasonably 
             low. Footnote oxygen uncertain, ODF recommends deletion.
211 @4483db  Not sure what happened, but oxygen unreasonably 
             low. Footnote oxygen uncertain, ODF recommends deletion.
212 @4650db  Not sure what happened, but oxygen unreasonably 
             low. Footnote oxygen uncertain, ODF recommends deletion.
227 @ 603db  Not sure what happened, but oxygen unreasonably 
             low. Footnote oxygen uncertain, ODF recommends deletion.

STATION 035

107 @ 232db  Sample log: Spigot hard to operate. Data looks 
             okay.

STATION 036

126 @2519db  Sample log: Leaky - air vent open, never 
             closed. Data looks good.

STATION 037

108 @ 237db  Sample log: Slight air leak. Doesn't seem to 
             have affected oxygen, agrees with CTDO.
124 @2028db  Delta-S at 2028db is .0052. No notes. No 
             problems noted, footnote salinity uncertain. Other samples 
             appear to be okay.
128 @2642db  Oxygen high doesn't fit station profile or 
             CTDO. No notes regarding problems. Footnote oxygen 
             uncertain, ODF recommends deletion.
133 @3801db  Tsuchiya: "O2 too high?" Oxygen high doesn't 
             fit station profile or CTDO. No notes regarding problems. 
             Footnote oxygen uncertain, ODF recommends deletion.

STATION 039

108 @ 228db  Sample log: Air leak. Oxygen a little high 
             compared with CTDO, okay vs. adjoining stations. Footnote 
             oxygen bad, bottle leaking.
112 @ 351db  Oxygen appears a little low as compared with 
             CTDO and adjoining stations. Footnote oxygen uncertain.
132 @3550db  PO4 .01 looks a little high, but well within 
             the accuracy of the measurement. Reread chart and if it is 
             .001 too high then so is 131. Footnote po4 uncertain.

STATION 040

1nut         Nutrients: PO4-Peaks poor; shift between 24 & 25 real. 
             Reason unknown. Cleaned system with RBS, rinsed with DiH20. 
             Replenish hydrazine. Nutrients: DW baseline high at end. May 
             be all shifted after 24, samples 124- 136. Footnote po4 
             uncertain.
104 @ 109db  Sample log: Slight air leak - valve not tight 
             enough. Samples appear to be okay, agree with adjoining 
             stations.
117 @ 907db  Sample log: Air leak. Samples appear to be 
             okay, agree with adjoining stations.
125 @2427db  Footnote po4 bad, see 1nut comment.
126 @2680db  Footnote po4 bad, see 1nut comment.
127 @2939db  Footnote po4 bad, see 1nut comment.
128 @3195db  Sample log: Broken top lanyard - broke while 
             separating rosettes. Samples appear to be okay, agree with 
             adjoining stations. Footnote po4 bad, see 1nut comment.
129 @3445db  Footnote po4 bad, see 1nut comment.
130 @3704db  Footnote po4 bad, see 1nut comment.
131 @3959db  Footnote po4 bad, see 1nut comment.
132 @4214db  Footnote po4 bad, see 1nut comment.
133 @4474db  Footnote po4 bad, see 1nut comment.
134 @4730db  Footnote po4 bad, see 1nut comment.
135 @4997db  Footnote po4 bad, see 1nut comment.
136 @5278db  Footnote po4 bad, see 1nut comment. Appears 
             that 36 tripped with 35, leave as is but footnote samples 
             uncertain.

STATION 041

1nut         Tsuchiya: "Deep PO4 level looks slightly low. Calc 
             okay, ragged end baseline.
117 @ 921db  Oxygen appears high as compared with adjoining 
             stations. Footnote o2 uncertain.
119 @1220db  Oxygen appears high as compared with adjoining 
             stations. Footnote o2 uncertain.
124 @2333db  Oxygen appears high as compared with adjoining 
             stations. Footnote o2 uncertain.
126 @2735db  Oxygen appears high as compared with adjoining 
             stations. Footnote o2 uncertain.
130 @3759db  Sample log: Slight air leak, helium redraw. 
             Oxygen appears to be okay.
134 @4787db  Oxygen appears high as compared with adjoining 
             stations. Footnote o2 uncertain.
136 @5240db  Sample log: Air leak. Oxygen appears to be 
             okay.

STATION 042

101 @ 1db    Sample log: Slight air leak. Samples appear to be 
             okay, agree with adjoining stations and CTD data.
106 @ 195db  Sample log: Colder? The samples indicate this 
             bottle mistripped and leaked, water samples fit the station 
             profile between 800-1800 db. The oxygen draw temperature is 
             7.5 which indicates water at 800db and sil at 1600-1800db. 
             Delete salinity, o2, sil, no3, no2, po4, 34.5793 85.6 145.01 
             39.51 0.01 2.75, respectively.
108 @ 254db  Sample log: Slight air leak. Samples appear to 
             be okay, fit station profile.
112 @ 509db  Sample log: Top valve open. Samples appear to 
             be okay, o2 agrees with Station 43 and CTDO.
113 @ 606db  The samples indicate this bottle mistripped and 
             leaked, water samples fit the station profile shallower than 
             scheduled. Delete salinity, o2, sil, no3, no2, po4, 34.8888 
             230.3 3.81 0.66 0.01 0.18, respectively.
122 @2025db  Oxygen appears high, calc okay, uncertain.
126 @2834db  Oxygen appears high, calc okay, uncertain.
130 @3800db  Sample log: Slight air leak. Samples appear to 
             be okay, o2 agrees with CTDO.

STATION 044

108 @ 201db  Sample log: Air leak. Samples appear to be 
             okay, oxygen agrees with CTDO.
115 @ 708db  Tsuchiya: "O2 too high." Footnote oxygen 
             uncertain, .1 high compared with CTDO.
116 @ 811db  Tsuchiya: "O2 too low. Okay compared with CTDO.
117 @ 914db  Sample log: Air leak. Samples appear to be 
             okay, oxygen agrees with Sta 042, but .1 high compared with 
             CTDO. Footnote bottle air leak and footnote o2 bad, for 
             other gas investigators. Tsuchiya: "O2 too high."
118 @1011db  Suspect buret not zeroed before fill, footnote 
             bad ODF recommends deletion.
131 @3959db  Sample log: Air leak. Samples appear to be 
             okay, o2 agrees with adjoining stations.
136 @5348db  Oxygen high footnote bad, other samples appear 
             to be okay.

STATION 045

101 @ 2db    Sample log: Slight air leak. Samples appear to be 
             okay.
109 @ 355db  Sample log: Vent open. Oxygen high, salinity 
             low as compared with adjacent stations, oxygen agrees with 
             Stas. 040 and 041. Footnote salinity and oxygen bad, bottle 
             leaking.
116 @ 914db  Oxygen low as compared with adjacent stations 
             and CTDO. Footnote o2 uncertain.
130 @3805db  Sample log: Slight air leak. Samples appear to 
             be okay.
136 @5385db  Sample log: Air leak. Samples appear to be 
             okay.

STATION 046

1no3         NO3 agrees with Station 043, the analyst on these 
             stations were the same. This same analysts did the analysis 
             on Station 048. Station 048 agrees with the other analyst's 
             results. No analytical problems were found. The no3 ending 
             standard is a little low compared to two adjoining stations, 
             but no problem was found. Footnote 17-36 as uncertain per 
             Talley request.
217 @ 909db  Talley: "Nitrate looks too high, 17-36." See 
             1no3 comments, footnote no3 uncertain.
218 @1006db  See 217 comment, footnote no3 uncertain.
219 @1212db  See 217 comments, footnote no3 uncertain.
220 @1412db  See 217 comments, footnote no3 uncertain.
221 @1618db  See 217 comments, footnote no3 uncertain.
222 @1819db  See 217 comments, footnote no3 uncertain.
223 @2020db  See 217 comments, footnote no3 uncertain.
224 @2273db  See 217 comments, footnote no3 uncertain.
225 @2532db  See 217 comments, footnote no3 uncertain.
226 @2786db  See 217 comments, footnote no3 uncertain.
227 @3039db  See 217 comments, footnote no3 uncertain.
228 @3299db  See 217 comments, footnote no3 uncertain.
229 @3548db  See 217 comments, footnote no3 uncertain.
230 @3808db  Sample log: Slow leak. Samples appear to be 
             okay. See 217 comments, footnote no3 uncertain.
231 @4062db  See 217 comments, footnote no3 uncertain.
232 @4316db  See 217 comments, footnote no3 uncertain.
233 @4577db  See 217 comments, footnote no3 uncertain.
234 @4838db  See 217 comments, footnote no3 uncertain.
235 @5099db  See 217 comments, footnote no3 uncertain.
236 @5345db  See 217 comments, footnote no3 uncertain.

STATION 047

112 @ 505db  Sample log: Air vent open. Samples appear to be 
             okay.
123 @2228db  Tsuchiya: PO4 too high? Calc and peaks okay.

STATION 048

107 @ 234db  Sample log: Air leak. Oxygen appears high 
             compared with adjoining stations and CTDO. Footnote bottle 
             leaking, and footnote o2 bad.
118 @1415db  Sample log: Lanyard broke, endcap popped during 
             separation. Samples appear to be okay.
122 @2199db  Suspect that salinity was drawn incorrectly. 
             Suspect a bottle leak that may have only been detected in 
             salinity since it is the last parameter drawn from a bottle, 
             footnote salinity bad, ODF recommends deletion of salinity, 
             and caution to other sample investigators. Suspect this 
             bottle had a slight leak. Intermittent problems were found 
             in the data from this station to 77, when the bottle was 
             changed. Sometimes the data was not effected. Oxygen was 
             investigated on each of these stations. All samples except 
             salinity look okay. At Station 74 per a note in the deck log 
             the spring was changed on the bottle, but the salts are 
             still low and don't agree with the CTD until Station 078 at 
             which time the bottle was replaced.
132 @4316db  NO3 poor peak. Data agrees with overlay plot of 
             adjoining stations.
134 @4837db  NO3 poor peak. Data agrees with overlay plot of 
             adjoining stations.

STATION 049

115 @ 704db  Oxygen a little low compared with CTDO, 
             footnote o2 uncertain.
122 @1819db  See station 048 comment regarding leaking 
             bottle. Samples appear to be okay, however see Station 048 
             leaking bottle comment.

STATION 050

1po4         Tsuchiya: "Deep po4 level too low?" Adjustment made 
             for std/baseline problem. End sw is .106 but .096 used. 
             Beginning and ending standards unlike surrounding stations. 
             Bad Beginning baseline, bad seawater, Phosphate data 
             unreliable, footnote bad.
101 @ 0db    Sample log: Air leak. Samples appear to be okay. 
             See 1po4 comment, footnote po4 bad.
102 @ 26db   See 1po4 comment, footnote po4 bad.
103 @ 114db  See 1po4 comment, footnote po4 bad.
104 @ 154db  See 1po4 comment, footnote po4 bad. Delta-S at 
             154db is -.0563. Calc okay.
105 @ 180db  See 1po4 comment, footnote po4 bad.
106 @ 204db  See 1po4 comment, footnote po4 bad.
107 @ 232db  See 1po4 comment, footnote po4 bad.
108 @ 263db  See 1po4 comment, footnote po4 bad. Sample log: 
             Slight air leak. Oxygen appears high compared to station 
             profile. Footnote bottle leaking, o2 bad.
109 @ 303db  See 1po4 comment, footnote po4 bad.
110 @ 354db  See 1po4 comment, footnote po4 bad.
111 @ 405db  See 1po4 comment, footnote po4 bad.
112 @ 504db  See 1po4 comment, footnote po4 bad.
113 @ 607db  See 1po4 comment, footnote po4 bad.
114 @ 713db  See 1po4 comment, footnote po4 bad.
115 @ 814db  See 1po4 comment, footnote po4 bad.
116 @ 900db  See 1po4 comment, footnote po4 bad.
117 @1009db  See 1po4 comment, footnote po4 bad.
118 @1215db  See 1po4 comment, footnote po4 bad.
119 @1417db  See 1po4 comment, footnote po4 bad.
120 @1627db  See 1po4 comment, footnote po4 bad.
121 @1828db  See 1po4 comment, footnote po4 bad.
122 @2029db  See 1po4 comment, footnote po4 bad. Delta-S at 
             2029db is -.0037. Samples appear to be okay, however see 
             Station 048 leaking bottle comment.
123 @2231db  See 1po4 comment, footnote po4 bad.
124 @2434db  See 1po4 comment, footnote po4 bad.
125 @2640db  See 1po4 comment, footnote po4 bad.
126 @2833db  See 1po4 comment, footnote po4 bad.
127 @3038db  See 1po4 comment, footnote po4 bad.
128 @3298db  See 1po4 comment, footnote po4 bad.
129 @3541db  See 1po4 comment, footnote po4 bad.
130 @3797db  See 1po4 comment, footnote po4 bad. Sample log: 
             Air leak. Samples appear to be okay.
131 @4044db  See 1po4 comment, footnote po4 bad.
132 @4303db  See 1po4 comment, footnote po4 bad.
133 @4564db  See 1po4 comment, footnote po4 bad.
134 @4823db  Oxygen appears to be slightly high. Footnote 
             oxygen uncertain. See 1po4 comment, footnote po4 bad.
135 @5065db  See 1po4 comment, footnote po4 bad.
136 @5269db  See 1po4 comment, footnote po4 bad.

STATION 051

106 @ 141db  Delta-S at 141db is -.0605. Salinity inversion 
             could be real. Footnote salinity uncertain.
122 @1718db  Samples appear to be okay, however see Station 
             048 leaking bottle comment.
130 @3451db  Sample log: Slight air leak. Samples appear to 
             be okay, fit adjoining station and CTDO very well.

STATION 052

101 @ 0db    Sample log: Slight air leak. Samples agree with 
             adjoining stations and CTD.
108 @ 258db  Sample log: Slight air leak. Samples appear to 
             be okay.
122 @2023db  Samples appear to be okay, however see Station 
             048 leaking bottle comment.
126 @2837db  Oxygen high does not agree with CTDO or 
             adjoining stations, footnote o2 uncertain.
129 @3549db  Delta-S at 3549db is -.0033. Calc okay, 
             footnote o2 uncertain.
136 @5392db  Sample log: Air leak - caps large. Samples 
             appear to be okay agrees with Sta 047 and CTD.

STATION 053

119 @1217db  Tsuchiya: "PO4 too high?" Calc okay, peaks 
             fair.
122 @1825db  Tsuchiya: "NO3 too low?" Calc okay, peaks good. 
             Samples appear to be okay, however see Station 048 leaking 
             bottle comment.
123 @2030db  Tsuchiya: "NO3 too low?" Calc okay, peaks good.
124 @2227db  Tsuchiya: "NO3 too low?" Calc okay, peaks good.
125 @2428db  Tsuchiya: "NO3 too low?" Calc okay, peaks good.
126 @2631db  Tsuchiya: "NO3 too low?" Calc okay, peaks good.
127 @2834db  Tsuchiya: "NO3 too low?" Calc okay, peaks good.
128 @3039db  Tsuchiya: "NO3 too low?" Calc okay, peaks fair.
135 @4694db  Sil slightly low, poor peak. Footnote sil bad 
             analysis.
136 @4924db  Sample log: Air leak. NO3 .2 too high, sil 3. 
             too high, both had poor peaks. Oxygen agrees with adjoining 
             station and CTDO. Footnote no3 bad analysis, footnote sil 
             bad analysis.

STATION 054

106 @ 176db  Nutrients low, no problems noted, peaks 
             reasonable. Footnote nuts uncertain.
122 @1819db  Footnote salinity bad, bottle leaking. See 
             Station 048 comments.
130 @3294db  Sample log: Slight air leak. Oxygen slightly 
             low compared with adjacent stations, does agree with CTDO, 
             footnote oxygen bad, bottle leaking. Other samples appear to 
             be okay.

STATION 055

101 @ 1db    Sample log: Slight air leak. Samples agree with 
             adjoining stations.
107 @ 198db  Sample log: Air leak. Oxygen appears to be okay 
             as well as other samples.
108 @ 229db  Sample log: Slight air leak. Oxygen low on CTDO 
             trace. Footnote bottle air leak, and footnote o2 bad.
115 @ 605db  Tsuchiya: "PO4 too low?" Calc okay, peaks fair.
116 @ 708db  Tsuchiya: "PO4 too low?" Calc okay, peaks fair.
122 @1720db  Samples appear to be okay, however see Station 
             048 leaking bottle comment.
126 @2527db  Oxygen high, may have been a duplicate draw 
             with 27. Footnote oxygen uncertain, ODF recommends deletion.
130 @3405db  Sample log: Slight air leak. Oxygen agrees with 
             CTDO and adjoining station.

STATION 056

108 @ 205db  Sample log: Slight air leak. Samples agree with 
             Station 057.
122 @1818db  Samples appear to be okay, however see Station 
             048 leaking bottle comment.
129 @3243db  Sample log: Red sea slime on spout. Samples 
             agree with adjoining station.

STATION 057

2nut         Tsuchiya: "Verify that the increase in all nutrients 
             below about 2000db from Station 057 to 058 is real." Calc 
             and peaks okay. 057 similar to 059. Nutrients: New "B" std 
             used "WOCE B" jun 21
217 @1011db  Sample log: Slow leak. Samples agree with 
             adjoining stations.
222 @2020db  Footnote salinity bad, bottle leaking. See 
             Station 048 comments.
230 @3462db  Sample log: Slow leak. Samples agree with 
             adjoining stations.
233 @4217db  Sample log: Oxygen? Bubble in cannula. Oxygen 
             agrees with adjoining stations, okay as is.

STATION 058

1nut         Tsuchiya: "Verify that the increase in all nutrients 
             below about 2000db from Station 057 to 058 is real." Calc 
             and peaks okay.
1sil         Silicate F1 (B and E) are higher than adjoining 
             stations. Footnote sil uncertain.
101 @ 0db    Sample log: Small air leak. Samples appear to be 
             okay, fit station profile.
108 @ 170db  Sample log: Small air leak. Salinity low 
             compared to CTD, but samples appear to fit station profile.
117 @ 812db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
118 @ 908db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
119 @1113db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
120 @1315db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
121 @1515db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
122 @1722db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain. Samples appear to be okay, however 
             see Station 048 leaking bottle comment.
123 @1923db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
124 @2124db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
125 @2325db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
126 @2526db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
127 @2733db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
128 @2936db  Talley: "Nitrate looks too high, 17-36." 
             Footnote no3 uncertain.
129 @3195db  Talley: "Sil looks a little high, 29-36." See 
             1sil comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.
130 @3448db  Sample log: Air leak. Samples appear to be 
             okay. Talley: "Sil looks a little high, 29-36." see 1sil 
             comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.
131 @3702db  Talley: "Sil looks a little high, 29-36." See 
             1sil comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.
132 @3963db  Talley: "Sil looks a little high, 29-36." See 
             1sil comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.
133 @4212db  Talley: "Sil looks a little high, 29-36." See 
             1sil comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.
134 @4472db  Talley: "Sil looks a little high, 29-36." See 
             1sil comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.
135 @4733db  Talley: "Sil looks a little high, 29-36." See 
             1sil comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.
136 @4978db  Talley: "Sil looks a little high, 29-36." See 
             1sil comment, footnote uncertain. Talley: "Nitrate looks too 
             high, 17-36." Footnote no3 uncertain.

STATION 059

1all         Sample log: 3-4-7-5-6-8. This was the order on 
             rosette. Bottles were put on rosette out of sequence.
1nut         Nutrients: New NO2 IO std; new cd column conditioned. 
             Cd column may need a little more conditioning-it will get 
             better. Footnote no3 uncertain.
101 @ 0db    Sample log: Air leak. Samples appear to be okay, 
             agree with adjoining stations and CTD.
108 @ 151db  Sample log: Air leak. Samples appear to be 
             okay, agree with adjoining stations and CTD.
114 @ 554db  Oxygen appears high. Calc okay, no problems 
             noted. Footnote o2 uncertain.
117 @ 855db  Sample log: Air leak. Samples appear to be 
             okay, agree with adjoining stations and CTD.
118 @1011db  Talley: "Nitrate high, 118-136." See comments 
             made by nutrient analyst, footnote no3 uncertain.
119 @1213db  See 118 comments, footnote no3 uncertain.
120 @1412db  See 118 comments, footnote no3 uncertain.
121 @1633db  See 118 comments, footnote no3 uncertain.
122 @1881db  Delta-S -.009, other samples agree with station 
             profile and adjoining stations. Footnote salinity bad, 
             bottle leaking. See Station 048 comments. See 118 comments, 
             footnote no3 uncertain.
123 @2129db  See 118 comments, footnote no3 uncertain.
124 @2326db  See 118 comments, footnote no3 uncertain.
125 @2532db  See 118 comments, footnote no3 uncertain.
126 @2740db  See 118 comments, footnote no3 uncertain.
127 @2940db  See 118 comments, footnote no3 uncertain.
128 @3143db  See 118 comments, footnote no3 uncertain.
129 @3346db  See 118 comments, footnote no3 uncertain.
130 @3548db  Sample log: Air leak. Samples appear to be 
             okay, agree with adjoining stations and CTD. See 118 
             comments, footnote no3 uncertain.
131 @3752db  See 118 comments, footnote no3 uncertain.
132 @4008db  See 118 comments, footnote no3 uncertain.
133 @4264db  See 118 comments, footnote no3 uncertain.
134 @4521db  See 118 comments, footnote no3 uncertain.
135 @4779db  See 118 comments, footnote no3 uncertain.
136 @4978db  See 118 comments, footnote no3 uncertain.

STATION 060 

106 @ 117db  Sample log: Vent valve open. Samples appear to 
             be okay for shallow water.
122 @1613db  Samples appear to be okay, however see Station 
             048 leaking bottle comment.
130 @3444db  Sample log: Slight air leak. Samples appear to 
             be okay, agree with adjoining stations and station profile.

STATION 061

1all         Console ops: Pylon 2 first for freon bottle blanks. 
             Tripped 12-1 then 36-13.
106 @3400db  No problems noted, other samples appear to be 
             okay, appears to be a drawing problem. Footnote o2 
             uncertain, ODF recommends deletion.
122 @ 353db  Delta-S is -.2081. No notes, calc okay, but 
             salinity obviously wrong. Other samples appear to be okay. 
             See Station 048 comments. Footnote bottle leaking, salinity 
             bad.
134 @2078db  Sample log: Bottom end cap popped during 
             separation-no water.
136 @2377db  Sample log: Leaking from bottom end cap after 
             vent open. Oxygen as well as other samples appear to be 
             okay.

STATION 062

119 @1212db  The oxygen is low, nitrate is high, phosphate 
             is high, silicate is high, salinity and oxygen agree with 
             CTD trace. leave as is, footnote o2 uncertain, no3, po4, 
             sil, and no2 uncertain.
122 @1818db  Sample log: Broken lanyard - empty bottle.

STATION 063

101 @ 0db    Sample log: Slight air leak. Samples appear to be 
             okay.
112 @ 458db  Sample log: Vent cock wide open. Oxygen high 
             compared with CTD and salinity low. Other samples appear to 
             be okay, footnote bottle leaking, footnote salinity and o2 
             bad.
117 @1010db  Sample log: Vent cock not tight. Samples appear 
             to be okay.
122 @2026db  Delta-S at 2026db is -.0062. All samples except 
             salinity look okay. Footnote salinity bad, bottle leaking. 
             See Station 048 comments.
129 @3245db  Sample log: Spigot broken on recovery (nuts and 
             salts taken), no o2 drawn.
130 @3449db  Sample log: Spigot broken on recovery (nuts and 
             salts taken), no o2 drawn.
131 @3704db  Sample log: Spigot broken on recovery (nuts and 
             salts taken), no o2 drawn.

STATION 064

122 @1719db  Delta-S at 1719db is -.0093. All samples except 
             salinity look okay. Footnote salinity bad, bottle leaking. 
             ODF recommends deletion of salinity. See Station 048 
             comments.
128 @2941db  Sample log: Air leak. Oxygen low compared with 
             CTDO, but agrees with adjoining station. Sil high compared 
             with adjoining station. Other samples appear to be okay. 
             Footnote o2 bad, footnote silicate bad, footnote bottle 
             leaking.
130 @3397db  Sample log: Slight air leak. Oxygen low 
             compared with CTDO, but agrees with adjoining station. Other 
             samples appear to be okay. Footnote o2 bad, bottle leaking, 
             may have effected all gas samples.

STATION 065

108 @ 202db  Sample log: Leak. Salinity and Oxygen agree 
             with CTD. Other samples also appear to be okay.
122 @2021db  Delta-S at 2021db is -.0074. Oxygen draw temp a 
             little high, but all samples except salinity look okay. 
             Footnote salinity bad, bottle leaking. ODF recommends 
             deletion of salinity. See Station 048 comments.
127 @2868db  Silicate appears high, poor peak, footnote sil 
             bad.
128 @3041db  Silicate appears low, poor sil peak, sample 
             rerun, and not improved, footnote sil bad.
130 @3498db  Sample log: Leak. Delta-S at 3498db is -.0030, 
             but deep samples are a little low compared to CTD. Oxygen 
             agrees with CTD. Other samples appear to be okay. Talley: 
             Footnote salinity uncertain. Salinity is slightly lower than 
             CTD and adjoining stations. No analytical problems noted.
131 @3755db  Talley: Footnote salinity uncertain. Salinity 
             is slightly lower than CTD and adjoining stations. No 
             analytical problems noted.
132 @4014db  Talley: Footnote salinity uncertain. Salinity 
             is slightly lower than CTD and adjoining stations. No 
             analytical problems noted.
133 @4268db  Talley: Footnote salinity uncertain. Salinity 
             is slightly lower than CTD and adjoining stations. No 
             analytical problems noted.
134 @4523db  Delta-S at 4523db is -.0036. Talley: Footnote 
             salinity uncertain. Salinity is slightly lower than CTD and 
             adjoining stations. No analytical problems noted.
135 @4787db  Delta-S at 4787db is -.0031. Talley: Footnote 
             salinity uncertain. Salinity is slightly lower than CTD and 
             adjoining stations. No analytical problems noted.
136 @5011db  Delta-S at 5011db is -.0035. Talley: Footnote 
             salinity uncertain. Salinity is slightly lower than CTD and 
             adjoining stations. No analytical problems noted.

STATION 066

207 @ 128db  Sample log: Air leak. Salinity and oxygen agree 
             with CTD, other samples also look okay.
208 @ 153db  Sample log: Slight air leak. Salinity and 
             oxygen agree with CTD, other samples also look okay.
222 @1615db  Delta-S at 1615db is -.0082. Footnote salinity 
             bad, bottle leaking. See Station 048 comments.
230 @3350db  Sample log: Slow air leak. Salinity and oxygen 
             agree with CTD, other samples also look okay.

STATION 067

117 @ 806db  Tsuchiya: "PO4 too low? (A small minimum in the 
             major maximum looks strange.)" Calc okay, peaks fair.
118 @ 909db  Tsuchiya: "PO4 too low? (A small minimum in the 
             major maximum looks strange.)" Calc okay, peaks fair. 
             Nutrients: 18 & 20 in rack wrong, 18 must be 20 otherwise 
             N&P max not right. Sil, no3 look okay so however analyst 
             arranged samples must be okay.
122 @1718db  Delta-S at 1718db is -.0092. Footnote salinity 
             bad, bottle leaking. See Station 048 comments.
128 @2905db  PO4 high, footnote po4 uncertain.
129 @3087db  Sample log: "Spigot broken off during recovery 
             - drew nuts & salts, no o2 drawn." Delta-S at 3087db is -
             .0032. Samples appear to be okay.
130 @3345db  Sample log: "Spigot broken off during recovery 
             - drew nuts & salts, no o2 drawn." PO4 is slightly high 
             compared with adjoining station, but there seems to be a 
             feature displayed in the shallower and deeper PO4 samples.

STATION 068

1po4         Tsuchiya: "Deep (>800m) po4 level is higher than 
             neighboring stations." Calc okay, peaks fair to good. Leave 
             as is.
1sil         Nutrients: Sil end sw odd. Tsuchiya: "Deep sil level 
             is higher than neighboring stations." Calc okay, peaks fair 
             to good. Leave as is.
101 @ 0db    Sample log: Leaky air. Salinity and oxygen agree 
             with CTD, other samples also appear to be okay.
108 @ 128db  Sample log: "Slight air leak." Oxygen trace is 
             different between adjoining stations and oxygen is high 
             compared with CTD. Leave as is.
122 @1619db  Delta-S at 1619db is -.0033. All samples except 
             salinity look okay. Footnote salinity bad, bottle leaking. 
             See Station 048 comments.
136 @4806db  Sample log: Air leak. Salinity and oxygen agree 
             with CTD, other samples also appear to be okay.

STATION 069

1po4         Tsuchiya: "Deep (>800m) po4 level is higher than 
             neighboring stations." Calc okay, peaks fair to good. Leave 
             as is.
1sil         Tsuchiya: "Deep sil level is higher than neighboring 
             stations." Calc okay, peaks fair to good. Leave as is.
101 @ 0db    Sample log: Slight air leak. Salinity and oxygen 
             agree with CTD, other samples also appear to be okay.
108 @ 152db  Sample log: Slight air leak. Oxygen a little 
             high compared with CTD, other samples also appear to be 
             okay.
113 @ 507db  Sample log: Dribbling from bottom cap. Salinity 
             and oxygen agree with CTD, other samples also appear to be 
             okay.
117 @ 911db  Sample log: Slight air leak - vent cock not 
             tight. Oxygen appears a little high compared with CTD, other 
             samples appear to be okay. Leave as is.
122 @1817db  Delta-S at 1817db is -.0055. All samples except 
             salinity look okay. Footnote salinity bad, bottle leaking. 
             See Station 048 comments.
127 @2687db  Oxygen too high, suspect drawing or analyst 
             error, footnote oxygen uncertain. ODF recommends deletion of 
             oxygen.
130 @3301db  Sample log: Air leaker. Salinity and oxygen 
             agree with CTD, other samples also appear to be okay.
136 @4807db  Sample log: Major air leak. Salinity and oxygen 
             agree with CTD, other samples also appear to be okay.

STATION 070

107 @ 77db   Sample log: Bottle didn't close, no water.
111 @ 243db  Sample log: Bottle didn't close, no water.
122 @1618db  Delta-S is -.0039. Footnote salinity bad, 
             bottle leaking. ODF recommends deletion of salinity. See 
             Station 048 comments.
130 @3298db  Sample log: Slight air leak. Salinity and 
             oxygen agree with CTD, sil appears a little high as compared 
             with adjoining station, but suspect analysis before bottle 
             problem.

STATION 071

1all         Sample log: Split sampling crew.
101 @ 0db    Sample log: Air leak. Samples appear to be okay.
115 @ 708db  Sample log: TCO2 sampler late.
116 @ 807db  Sample log: TCO2 sampler late.
122 @1820db  Delta-S at 1820db is -.0343. ODF recommends 
             deletion of salinity. Oxygen draw temp a little low, but all 
             samples except salinity look okay. Footnote salinity bad, 
             bottle leaking. See Station 048 comments.

STATION 072

108 @ 161db  Sample log: Air leak. Salinity and oxygen agree 
             with CTD, other samples are also okay.
112 @ 356db  Sample log: Air valve open. Salinity and oxygen 
             agree with CTD, other samples are also okay.
122 @1613db  Delta-S at 1613db is -.0060. ODF recommends 
             deletion. Suspect a problem with this bottle. Oxygen draw 
             temp a little high, but all samples except salinity look 
             okay. Footnote salinity bad, bottle leaking. See Station 048 
             comments.
129 @3040db  Sample log: Water leak around spigot. Salinity 
             and oxygen agree with CTD, other samples are also okay.
130 @3291db  Sample log: Air leak. Salinity and oxygen agree 
             with CTD, other samples are also okay.

STATION 073

1po4         Tsuchiya: "Deep (>800m) po4 level is higher than 
             neighboring stations." Calc okay, peaks fair to good. Leave 
             as is.
101 @ 0db    Sample log: Dribble leaker out of spigot. Delta-S 
             at 0db is .0516. Samples appear to be okay for surface 
             sample.
104 @ 77db   Sample log: Water leak from bottom. Samples 
             appear to be okay.
122 @1620db  Delta-S at 1620db is -.0206. ODF recommends 
             deletion. Suspect a problem with this bottle. All samples 
             except salinity look okay. Footnote salinity bad, bottle 
             leaking. See Station 048 comments.
129 @2984db  Sample log: Water leak out of bottom and 
             stopper. Samples appear to be okay.
130 @3190db  Sample log: Air leak. Samples appear to be 
             okay.

STATION 074

1no3         Tsuchiya: "Near-bottom no3 slightly too high?" 
             Nutrients: Serious no3 drift-looks linear. Make no3 ddw same 
             as sw begin & end.
106 @ 88db   Bottle reversed early, footnote bottle leaking. 
             Delete salinity, o2, sil, no3, no2, po4, 34.6952 86.7 73.95 
             28.16 0.29 1.97, respectively.
122 @1615db  Delta-S at 1615db is -.0221. ODF recommends 
             deletion. All samples except salinity look okay. Footnote 
             salinity bad, bottle leaking. See Station 048 comments.
130 @3290db  Sample log: Slight air leak. Oxygen appears 
             high compared with two adjoining stations, but okay as 
             compared with 7 other stations. Footnote o2 bad, footnote 
             bottle leaking. Other samples appear okay.
135 @4586db  Oxygen low, footnote o2 uncertain.

STATION 075

1no3         Tsuchiya: "Near-bottom no3 slightly too high?" 
             Nutrients: New photo tube-no3. Cleaned cd column.
1nut         Tsuchiya: "All three nuts in deep water (>1000m) 
             decrease from Station 075 to 076." Calc and peaks okay. 
             Leave for now.
101 @ 0db    Sample log: Slow leak. Oxygen high vs. CTD and 
             Sta 074.
116 @ 704db  Sample log: Dripping from spigot. Salinity and 
             oxygen agree with CTD, but oxygen low compared with 
             adjoining stations.
122 @1623db  Delta-S at 1623db is -.0218. Oxygen draw temp a 
             little high, but all samples except salinity look okay. 
             Footnote salinity bad, bottle leaking. See Station 048 
             comments.
129 @2870db  Oxygen low compared with CTD and adjoining 
             station. Footnote o2 uncertain.
130 @3044db  Sample log: Leaker from tap. Salinity and 
             oxygen agree with CTD, other samples also appear to be okay.


STATION 076

2nut         Tsuchiya: "All three nuts in deep water (>1000m) 
             decrease from Station 075 to 076." Nutrients: New working 
             Sncl2 & ss molyb. Calc and peaks okay. Leave for now.
201 @ 0db    Sample log: Slight air leak. Salinity low 
             compared with adjoining stations, but okay compared with 
             CTD. Oxygen high compared with CTD, but okay with adjoining 
             stations.
203 @ 81db   Sample log: Tiny bubbles. Samples appear to be 
             okay.
219 @1015db  Sample log: Oxygen bubbles from NaI cannula. 
             Oxygen profile looks okay.
222 @1620db  Delta-S at 1620db is -.0218. ODF recommends 
             deletion. Oxygen draw temp a little high, but all samples 
             except salinity look okay. Footnote salinity bad, bottle 
             leaking. See Station 048 comments.
225 @2225db  Sample log: Spigot hit ship. Sample log: Water 
             came out - sampled first for oxygen. Oxygen a little high 
             compared with CTD, footnote oxygen bad, bottle leaking, may 
             have effected other samples. Other samples appear to be 
             okay.
227 @2629db  Sample log: Tiny bubbles. Oxygen agrees with 
             CTD, other samples appear to be okay.
230 @3241db  Sample log: Slight air leak. Oxygen agrees with 
             CTD, other samples appear to be okay.

STATION 077

1all         Sample log: New battery in oxygen thermometer Sample 
             log: NaI/NaOH had bad bubble problem. Deep station profile 
             is a little higher than adjoining stations, footnote o2 
             uncertain as station comparisons indicate.
101 @ 0db    Sample log: Air leak. Salinity and oxygen agree 
             with CTD, other samples appear okay.
120 @1006db  Oxygen too high, looks like a drawing error 
             with 21. Footnote oxygen uncertain, ODF recommends deletion.
122 @1410db  Sample log: Leaking from bottom end cap. Delta-
             S at 1410db is -.0218. ODF recommends deletion. Oxygen 
             agrees with CTD. Oxygen draw temp a little high, but all 
             samples except salinity look okay. Footnote salinity bad, 
             bottle leaking. See Station 048 comments.
124 @1821db  Footnote o2 uncertain, see 1all comment. 
             Talley: "Leave oxygen as okay. Plots with stations 75-80 
             show that numbers fall within range and oxygen is going 
             through a fairly strong horizontal gradient." Leave oxygen 
             as good.
125 @2026db  Footnote o2 uncertain, see 1all comment. Leave 
             oxygen as good. See 124 Talley comment.
126 @2227db  Footnote o2 uncertain, see 1all comment. Leave 
             oxygen as good. See 124 Talley comment.
127 @2430db  Tsuchiya: "O2 slightly too high, could be 
             correct." Footnote o2 uncertain, see 1all comment. Leave 
             oxygen as good. See 124 Talley comment.
128 @2632db  Tsuchiya: "O2 slightly too low, could be 
             correct." Footnote o2 uncertain, see 1all comment. Leave 
             oxygen as good. See 124 Talley comment.
131 @3299db  Footnote o2 uncertain, see 1all comment. Leave 
             oxygen as good. See 124 Talley comment.
132 @3551db  Footnote o2 uncertain, see 1all comment. Leave 
             oxygen as good. See 124 Talley comment.

STATION 078

101 @ 0db    Sample log: Vent cock was not tight. Samples 
             appear to be okay.
108 @ 195db  Sample log: Slight leaker. Samples appear to be 
             okay.
111 @ 303db  Sample log: Leaking water out of bottom during 
             sampling. Samples appear to be okay.
112 @ 352db  Sample log: Leaking water out of bottom. 
             Samples appear to be okay.
119 @1009db  Sample log: Valve open (air). Samples appear to 
             be okay.
120 @1210db  Sample log: Valve open (air). Samples appear to 
             be okay.
121 @1422db  Sample log: Valve open (air). Footnote bottle 
             as leaking, it may only effect gas samples. Talley: "Leave 
             oxygen in data set and footnote bad." Done as per Talley 
             comment.
122 @1613db  Sample log: Valve open but not leaking. Samples 
             appear to be okay.

STATION 079

1sil         Tsuchiya: "SiO3 values in the major max (double 
             maximum) at ~3000m are slightly higher than those at 
             neighboring stations." Calc okay, peaks fair.
101 @ 0db    Sample log: Dribbled water from spigot. Samples 
             appear to be okay.
104 @ 112db  Sample log: Water leaker from bottom. Samples 
             appear to be okay.
131 @3245db  Sample log: 100+ orange biology over top half 
             of bottle. Samples appear to be okay.

STATION 080

1po4         Tsuchiya: Deep (>~1000m PO4 values systematically too 
             low. Calc okay, peaks fair.
101 @ 0db    Sample Log: Air leak. Oxygen agrees with 
             adjoining stations and CTDO.
108 @ 152db  Sample Log: Slight air leak. Oxygen agrees with 
             CTDO, other samples appear to be okay.
112 @ 310db  Oxygen too high, footnote oxygen uncertain, ODF 
             recommends deletion.
115 @ 537db  Sample log: Broken spigot, probably during 
             launch. No water samples.
130 @2959db  Sample Log: Slight air leak. Samples appear to 
             be okay, agree with adjoining stations and CTD.


STATION 081

161 @ 2db    Oxygen and nutrients were not drawn per sampling 
             schedule.
162 @ 36db   Oxygen and nutrients were not drawn per sampling 
             schedule.
163 @ 227db  Sample Log: Bottom end cap hung up.
164 @ 236db  Oxygen and nutrients were not drawn per 
             sampling schedule.
165 @ 700db  Sample Log: Bottom end cap hung up.
166 @ 797db  Oxygen and nutrients were not drawn per 
             sampling schedule.
167 @ 892db  Sample Log: Bottom end cap hung up. Too short.
168 @2606db  Delta-S at 2606db is -.0038. Oxygen and 
             nutrients were not drawn per sampling schedule.
169 @3525db  Oxygen and nutrients were not drawn per 
             sampling schedule.
170 @3978db  Sample Log: Bottom end cap hung up. Too short.
171 @4392db  Oxygen and nutrients were not drawn per 
             sampling schedule.

STATION 082

108 @ 135db  Sample Log: Small air leak. Samples appear to 
             be okay.

STATION 083

1all         Suspect 68 closed at 3037db and remaining bottles 
             closed one level lower than intended. No indication of two 
             trips from computer. Possibly crossed lanyard problem and 
             extra trip. Footnote bottles, did not trip correctly.
161 @ 26db   See 1all comment, oxygen and nutrients were not 
             drawn per sampling schedule.
162 @ 209db  See 1all comment, oxygen and nutrients were not 
             drawn per sampling schedule.
163 @ 414db  Delta-S at 414db is .0694, suspect tripping 
             problem. Footnote bottle leaking and salinity as bad, ODF 
             recommends deletion. See 1all comment, oxygen and nutrients 
             were not drawn per sampling schedule.
164 @ 606db  See 1all comment, oxygen and nutrients were not 
             drawn per sampling schedule.
165 @ 810db  See 1all comment, oxygen and nutrients were not 
             drawn per sampling schedule.
166 @1013db  See 1all comment, oxygen and nutrients were not 
             drawn per sampling schedule. Talley: Footnote salinity 
             uncertain. Many problems with these LADCP stations, suspect 
             this is another bottle or tripping problem and not the 
             analysis.
167 @2019db  Delta-S at 2019db is -.0319. Suspect bottle 
             leaking or tripping (tripped between scheduled trip and next 
             level). Footnote bottle leaking and salinity as bad, ODF 
             recommends deletion. See 1all comment, oxygen and nutrients 
             were not drawn per sampling schedule.
168 @3037db  See 1all comment, oxygen and nutrients were not 
             drawn per sampling schedule.
169 @3037db  Delta-S at 3037db is .0825. Suspect bottle 
             leaking or tripping (tripped between scheduled trip and next 
             level). Footnote bottle leaking and salinity as bad, ODF 
             recommends deletion. Oxygen and nutrients were not drawn per 
             sampling schedule.
170 @4060db  Oxygen and nutrients were not drawn per 
             sampling schedule.
171 @4434db  Oxygen and nutrients were not drawn per 
             sampling schedule.

STATION 084

1no3         NO3 high by about 3%, calculations good. Footnote no3 
             uncertain.
1nut         Tsuchiya: "Deep PO4, NO3, & SiO3 values too high 
             relative to nearby stations." PO4 stds (F1) averaged with 
             adjoining stations standard affected the samples incorrectly 
             per AWM. Station profile comparison now looks good for po4. 
             Nutrients: New imid buffer.
101 @ 30db   Sample Log: Air leak. Samples appear to be okay.
102 @ 72db   See 112
103 @ 92db   See 112
104 @ 103db  See 112
105 @ 113db  See 112
106 @ 130db  See 112
107 @ 155db  See 112
108 @ 207db  Sample Log: Slight air leak. Samples appear to 
             be okay. See 112
109 @ 257db  See 112
110 @ 307db  See 112
111 @ 352db  See 112
112 @ 1db    11 was tripped first through to 1 then 12 was 
             tripped at the surface, footnote bottles 1-12 did not trip 
             correctly. ODF is submitting the data in the proper 
             sequence, just not as originally scheduled.
119 @1011db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
120 @1213db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
121 @1413db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
122 @1615db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
123 @1818db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
124 @2024db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
125 @2225db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
126 @2431db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
127 @2637db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
128 @2833db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
129 @3037db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
130 @3242db  Sample Log: Slight air leak. Samples appear to 
             be okay. See 1nut & 1no3 comment, footnote no3 uncertain.
131 @3451db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
132 @3655db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
133 @3869db  Delta-S at 3869db is -.0033. See 1nut & 1no3 
             comment, footnote no3 uncertain.
134 @4071db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
135 @4288db  See 1nut & 1no3 comment, footnote no3 
             uncertain.
136 @4482db  See 1nut & 1no3 comment, footnote no3 
             uncertain.

STATION 085

161 @ 35db   Oxygen and nutrients were not drawn per sampling 
             schedule.
162 @ 208db  Oxygen and nutrients were not drawn per 
             sampling schedule.
163 @ 414db  Delta-S is 112.7. Suspect bottle tripping 
             problem, Footnote bottle 3 did not trip correctly, salinity 
             bad. ODF recommends deletion of salinity.
164 @ 614db  Oxygen and nutrients were not drawn per 
             sampling schedule.
165 @ 820db  Oxygen and nutrients were not drawn per 
             sampling schedule.
166 @1027db  Oxygen and nutrients were not drawn per 
             sampling schedule.
167 @2008db  Oxygen and nutrients were not drawn per 
             sampling schedule.
168 @3022db  Sample Log: Hung up, sliding bottom lanyard 
             hooked over junction on top lanyard.
169 @4043db  Delta-S is 73.0. Suspect bottle tripping 
             problem. Footnote bottle leaking and salinity bad. ODF 
             recommends deletion of salinity.
170 @4508db  Oxygen and nutrients were not drawn per 
             sampling schedule.
171 @ 2db    Sample Log: Not put on rosette - still in rack 
             during cast.

STATION 086

101 @ 66db    Sample Log: Air leak. Salinity and oxygen agree 
             with CTD.
102 @ 82db   Delta-S at 82db is -.0774. Salinity the same as 
             103. Slight inversion on CTD profile. Other shallow samples 
             appear reasonable.
103 @ 92db   See 112 comment.
104 @ 103db  See 112 comment.
105 @ 119db  See 112 comment.
106 @ 159db  See 112 comment.
107 @ 178db  See 112 comment.
108 @ 209db  See 112 comment.
109 @ 262db  See 112 comment.
110 @ 324db  See 112 comment.
111 @ 385db  See 112 comment.
112 @ 0db    11 was tripped first through to 1 then 12 was 
             tripped at the surface. ODF is submitting the data in the 
             proper sequence, just not as originally scheduled.
130 @3033db  Sample Log: Slight air leak. Samples appear to 
             be okay.

STATION 087

161 @ 3db    Oxygen and nutrients were not drawn per sampling 
             schedule.
162 @ 30db   Oxygen and nutrients were not drawn per sampling 
             schedule.
163 @ 187db  Oxygen and nutrients were not drawn per 
             sampling schedule.
164 @ 207db  Oxygen and nutrients were not drawn per 
             sampling schedule.
165 @ 259db  Oxygen and nutrients were not drawn per 
             sampling schedule.
166 @ 820db  Oxygen and nutrients were not drawn per 
             sampling schedule.
167 @ 921db  Oxygen and nutrients were not drawn per 
             sampling schedule.
168 @2054db  Oxygen and nutrients were not drawn per 
             sampling schedule.
169 @3089db  Delta-S is -78.3. Suspect bottle tripped 
             incorrectly. Footnote bottle leaking and salinity bad, ODF 
             recommends deletion. Oxygen and nutrients were not drawn per 
             sampling schedule.
170 @4128db  Talley: "Footnote salinity questionable. Maybe 
             it is a bottle problem." Footnote bottle leaking, footnote 
             salinity bad. Oxygen and nutrients were not drawn per 
             sampling schedule.
171 @4627db  Oxygen and nutrients were not drawn per 
             sampling schedule.

STATION 088

108 @ 155db  Sample Log: Slight air leak. Salinity and 
             oxygen agree with CTD.

STATION 089

161 @ 3db    Oxygen and nutrients were not drawn per sampling 
             schedule.
162 @ 36db   Oxygen and nutrients were not drawn per sampling 
             schedule.
163 @ 209db  Oxygen and nutrients were not drawn per 
             sampling schedule.
164 @ 414db  Oxygen and nutrients were not drawn per 
             sampling schedule.
165 @ 608db  Oxygen and nutrients were not drawn per 
             sampling schedule.
166 @ 813db  Oxygen and nutrients were not drawn per 
             sampling schedule.
167 @1012db  Oxygen and nutrients were not drawn per 
             sampling schedule.
168 @2008db  Oxygen and nutrients were not drawn per 
             sampling schedule.
169 @3039db  Delta-S is -.0350. Suspect bottle tripped 
             incorrectly. Footnote bottle leaking and salinity bad, ODF 
             recommends deletion. Oxygen and nutrients were not drawn per 
             sampling schedule.
170 @4050db  Oxygen and nutrients were not drawn per 
             sampling schedule.
171 @4538db  Delta-S is -.0914. Suspect bottle tripped 
             incorrectly. Footnote bottle leaking and salinity bad, ODF 
             recommends deletion. Oxygen and nutrients were not drawn per 
             sampling schedule.

STATION 090

101 @ 0db    Sample Log: Air leak. Salinity and oxygen agree 
             with CTD.
102 @ 0db    Suspect console operator did not trip properly. 
             Should have been at 30db.
130 @3044db  Sample Log: Slight air leak. Oxygen and 
             salinity agree with CTD, samples agree with adjoining 
             stations.

STATION 091

161 @ 3db    Oxygen and nutrients were not drawn per sampling 
             schedule.
162 @ 25db  Oxygen and nutrients were not drawn per sampling 
             schedule.
163 @ 217db  Oxygen and nutrients were not drawn per 
             sampling schedule.
164 @ 711db  Oxygen and nutrients were not drawn per 
             sampling schedule.
165 @ 815db  Oxygen and nutrients were not drawn per 
             sampling schedule.
166 @ 917db  Oxygen and nutrients were not drawn per 
             sampling schedule. Oxygen and nutrients were not drawn per 
             sampling schedule.
167 @2027db  Sample Log: Empty but closed - must have hung 
             up until out of water.
168 @2540db  Oxygen and nutrients were not drawn per 
             sampling schedule.
169 @3057db  Delta-S is -7.5, suspect that bottle either 
             tripped with 68 or that sample drawing error. Footnote 
             bottle leaking, salinity bad. Oxygen and nutrients were not 
             drawn per sampling schedule.
170 @4094db  Oxygen and nutrients were not drawn per 
             sampling schedule.
171 @4446db  Oxygen and nutrients were not drawn per 
             sampling schedule.

STATION 092

1sil         Tsuchiya: "Lower Sil values near the Sil max real?" 
             Calc and peaks okay. Tsuchiya may have made his comment 
             before entry was corrected. Entry error on f1(e) sil.
108 @ 133db  Sample Log: Slight air leak. Salinity and 
             oxygen agree with CTD, other samples appear to be okay.
127 @2223db  0xygen high, suspect duplicate draw with 28. 
             Footnote oxygen uncertain, ODF recommends deletion.
133 @3548db  Sil looks high, peak okay, leave as is, 
             Adjoining stations also show sil max.

STATION 093

161 @ 3db    Sample log: Assume duplicate nuts tubes drawn. (2 
             samples run at end of station 92). Oxygen differs by .021, 
             nuts are okay.
162 @ 56db   Oxygen and nutrients were not drawn per sampling 
             schedule.
163 @ 197db  Oxygen and nutrients were not drawn per 
             sampling schedule.
164 @ 213db  Oxygen and nutrients were not drawn per 
             sampling schedule.
165 @ 244db  Oxygen and nutrients were not drawn per 
             sampling schedule.
166 @ 820db  Oxygen and nutrients were not drawn per 
             sampling schedule.
167 @ 922db  Delta-S .024, salinity is the only sample 
             taken, bottle may have tripped incorrectly or leaked. 
             Footnote bottle leaking and salinity bad. Oxygen and 
             nutrients were not drawn per sampling schedule.
168 @2040db  Delta-S at 2040db is .0030. Oxygen and 
             nutrients were not drawn per sampling schedule.
169 @3058db  Oxygen and nutrients were not drawn per 
             sampling schedule.
170 @4095db  Oxygen and nutrients were not drawn per 
             sampling schedule.
171 @4381db  Sample log: Drain valve open. Salinity agrees 
             with CTD. Oxygen and nutrients were not drawn per sampling 
             schedule.


STATION 094

1nut         Tsuchiya: "Is the sudden decrease in deep PO4 values 
             real?" Calc and peaks okay. Nutrients: Fresh hydrazine, new 
             tartacid. Clean system with dil rbs. Notes by nutrient 
             analyst indicate that decrease is probably not real. 
             Footnote po4 uncertain 119-136. Talley: "These look okay." 
             Had footnoted these uncertain, change to okay.

STATION 095

161 @ 2db    Oxygen and nutrients not drawn.
162 @ 35db   Oxygen and nutrients not drawn.
163 @ 206db  Oxygen and nutrients not drawn.
164 @ 412db  Oxygen and nutrients not drawn.
165 @ 613db  Oxygen and nutrients not drawn.
166 @ 816db  Oxygen and nutrients not drawn.
167 @1025db  Oxygen and nutrients not drawn.
168 @2046db  Delta-S at 2046db is .0036. Oxygen and 
             nutrients not drawn.
169 @3081db  Delta-S is -.006. This bottle has been a 
             problem, footnote bottle leaking and salinity bad, ODF 
             recommends deletion. Oxygen and nutrients not drawn.
170 @4116db  Oxygen and nutrients not drawn.
171 @4272db  Oxygen and nutrients not drawn.

STATION 096

101 @ 0db    Sample Log: Big time air leak. Oxygen agrees with 
             CTD and adjoining station, other samples okay.
107 @ 111db  Sample Log: Air vent loose. Oxygen agrees with 
             CTD and adjoining station, other samples okay.
108 @ 125db  Sample Log: Slight air leak. Oxygen agrees with 
             CTD and adjoining station, salinity a little high compared 
             to CTD, other samples okay. Delta-S at 125db is -.0414.

STATION 097

161 @ 3db    Oxygen and nutrients were not drawn.
162 @ 19db   Oxygen and nutrients were not drawn.
163 @ 258db  Oxygen and nutrients were not drawn.
164 @ 820db  Oxygen and nutrients were not drawn.
165 @ 922db  Oxygen and nutrients were not drawn.
166 @1025db  Oxygen and nutrients were not drawn.
167 @1536db  Oxygen and nutrients were not drawn.
168 @2044db  Oxygen and nutrients were not drawn.
169 @2558db  Oxygen and nutrients were not drawn.
170 @3076db  Oxygen and nutrients were not drawn.
171 @3444db  Oxygen and nutrients were not drawn.

STATION 098

207 @ 177db  Sample log: A little air leak. Samples okay 
             @177db.
229 @3042db  Oxygen high, may be a drawing error with 28. 
             Footnote oxygen uncertain.
2all  Sample log: Oxygen draw temperature not accurate.
461 @ 3db    Nutrients not drawn per sampling schedule.
462 @1106db  Sample log: Air leak. Oxygen .13 too high, air 
             leak appears to have effected sample. Footnote bottle 
             leaking, o2 bad. Nutrients not drawn per sampling schedule.
463 @1310db  Nutrients not drawn per sampling schedule.
464 @1569db  Nutrients not drawn per sampling schedule.
465 @1771db  Nutrients not drawn per sampling schedule.
466 @1943db  Nutrients not drawn per sampling schedule.
467 @2118db  Nutrients not drawn per sampling schedule. 
             Sample log: Bottles are reversed in the rack. Salinity and 
             oxygen okay.
468 @2205db  Sample log: Bottles are reversed in the rack. 
             Delta-S at 2205db is .0035. Salinity and oxygen okay. 
             Nutrients not drawn per sampling schedule.
469 @2293db  Salinity and oxygen low @2293db. No analytical 
             notes, but usual hangup Footnote bottle leaking and salinity 
             and oxygen bad, ODF recommends deletion. Nutrients not drawn 
             per sampling schedule.
470 @2433db  Sample log: Put down with air valve open. 
             Salinity high, oxygen okay Footnote salinity bad, ODF 
             recommends deletion. Nutrients not drawn per sampling 
             schedule.
471 @4380db  Nutrients not drawn per sampling schedule.

STATION 099

161 @ 2db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 26db   Oxygen and nutrients not drawn per sampling 
             schedule.
163 @ 205db  Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 409db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 605db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @ 792db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1001db  Oxygen and nutrients not drawn per sampling 
             schedule. Delta-S at 1001db is .0238. No analytical problems 
             noted, suspect bottle leaking. Footnote bottle leaking and 
             salinity bad.
168 @2006db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @3032db  Oxygen and nutrients not drawn per sampling 
             schedule. Delta-S is -.015, either tripping problem or 
             leaking bottle. Footnote bottle leaking and salinity bad, 
             ODF recommends deletion.
170 @4057db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4286db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 101

161 @ 3db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 34db   Oxygen and nutrients not drawn per sampling 
             schedule.
163 @ 250db  Oxygen and nutrients not drawn per sampling 
             schedule. Sample Log: Air leak. Salinity looks okay.
164 @ 502db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 902db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @1006db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1509db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @2012db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @3022db  Oxygen and nutrients not drawn per sampling 
             schedule.
170 @4056db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4367db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 102

1all         Sample Log: Oxygen therm not working. Tsuchiya: "Deep 
             (>~1000m) NO3 & Sil look too low, relative to adjoining 
             stations." Calc and peaks okay.
104 @ 72db   Sample Log: Pet cock was open, air leak. Samples 
             look okay.
108 @ 169db  Sample Log: Air leak. Samples look okay.
120 @1217db  Talley: "NO3 looks too low, 120-136." No 
             analytical problems noted, footnote no3 uncertain.
121 @1418db  Footnote no3 uncertain, see 120 comment.
122 @1625db  Sample Log: Lanyard caught, empty.
123 @1827db  Footnote no3 uncertain, see 120 comment.
124 @2024db  Footnote no3 uncertain, see 120 comment.
125 @2195db  Footnote no3 uncertain, see 120 comment.
126 @2368db  Footnote no3 uncertain, see 120 comment.
127 @2531db  Footnote no3 uncertain, see 120 comment.
128 @2688db  Footnote no3 uncertain, see 120 comment.
129 @2861db  Footnote no3 uncertain, see 120 comment.
130 @3039db  Footnote no3 uncertain, see 120 comment.
131 @3245db  Footnote no3 uncertain, see 120 comment.
132 @3442db  Footnote no3 uncertain, see 120 comment.
133 @3646db  Footnote no3 uncertain, see 120 comment.
134 @3904db  Footnote no3 uncertain, see 120 comment.
135 @4154db  Footnote no3 uncertain, see 120 comment.
136 @4404db  Footnote no3 uncertain, see 120 comment.

STATION 103

161 @ 3db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 36db   Oxygen and nutrients not drawn per sampling 
             schedule.
163 @ 205db  Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 406db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 610db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @ 812db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1019db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @2049db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @3080db  Oxygen and nutrients not drawn per sampling 
             schedule. Salinity too low @3080db. Shipboard data analyst 
             indicates this bottle caused continuing problems. Footnote 
             bottle leaking and salinity bad, ODF recommends deletion.
170 @4116db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4358db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 104

108 @ 178db  Sample Log: Slight leak. Gradient area @178db, 
             leave as is.
130 @3036db  Delta-S at 3036db is .0038. Suspect drawing 
             error, sample taken from 31. Footnote salinity uncertain, 
             ODF recommends deletion.

STATION 105

161 @ 2db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 35db   Oxygen and nutrients not drawn per sampling 
             schedule.
163 @ 232db  Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 403db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 595db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @ 895db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1024db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @1901db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @2894db  Oxygen and nutrients not drawn per sampling 
             schedule. Salinity too low @2894db. Delta-S is -6.1 Footnote 
             bottle leaking and salinity bad, ODF recommends deletion. 
             Shipboard data analyst indicates this bottle caused 
             continuing problems.
170 @3923db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4554db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 106

101 @ 0db    Sample Log: Air leak. Samples appear to be okay.
108 @ 176db  Sample Log: Air leak. Samples appear to be 
             okay.

STATION 107

161 @ 2db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 29db   Sample Log: Slight air leak. Salinity sample 
             agrees with CTD. Oxygen and nutrients not drawn per sampling 
             schedule.
163 @ 92db   Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 242db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 319db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @ 879db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1085db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @1980db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @2980db  Oxygen and nutrients not drawn per sampling 
             schedule.
170 @4013db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4459db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 108

101 @ 0db    Sample Log: Slight leaker. Samples appear to be 
             okay.
108 @ 145db  Sample Log: Slight leaker. Oxygen appears low 
             as compared to adjoining stations. Footnote bottle leaking, 
             oxygen bad. Leaking comment appears to have effected gas 
             sample. Other samples appear okay.
125 @2130db  Sample Log: Retake for He.
131 @3382db  Sample Log: Retake for He. Delta-S at 3382db is 
             -.0030. Oxygen low, and no3, po4, sil high. Footnote o2 and 
             nutrients uncertain.
132 @3608db  Sample Log: Retake for He.

STATION 109

161 @ 3db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 232db  Oxygen and nutrients not drawn per sampling 
             schedule.
163 @ 509db  Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 606db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 898db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @1513db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1813db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @2526db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @3040db  Oxygen and nutrients not drawn per sampling 
             schedule.
170 @4037db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4348db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 110

101 @ 0db    Sample Log: Slight air leaker. Samples appear to 
             be okay.
108 @ 179db  Sample Log: Slight air leaker. Samples appear 
             to be okay.
130 @3036db  Sample Log: Redo He.

STATION 111

161 @ 2db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 34db   Sample Log: Small air leak. Salinity agrees with 
             CTD. Oxygen and nutrients not drawn per sampling schedule.
163 @ 237db  Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 411db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 616db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @ 819db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1018db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @1958db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @2961db  Oxygen and nutrients not drawn per sampling 
             schedule.
170 @3991db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4417db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 112

1all         Tsuchiya: "Deep (>1000m) PO4 too low." Nutrients: 
             Fresh hydrazine. Calc and peaks okay. Use mean of standards 
             from Stations 110 and 114. Station comparisons much better.
108 @ 145db  Sample Log: Slight air leak. Samples appear to 
             be okay.

STATION 113

161 @ 2db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 35db   Oxygen and nutrients not drawn per sampling 
             schedule. Sample Log: Slight air leak. Salinity agrees with 
             CTD.
163 @ 304db  Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 705db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 905db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @1203db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1508db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @2016db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @3016db  Oxygen and nutrients not drawn per sampling 
             schedule.
170 @4041db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4464db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 114

1all         Tsuchiya: "Deep (>~1000m) NO3 too high." Calc and 
             peaks okay.
101 @ 0db    Sample Log: Slight leaker. Samples appear to be 
             okay.
108 @ 152db  Sample Log: Slight leaker. Samples appear to be 
             okay.
117 @ 712db  Sample Log: Slight air leak, vent cock. Samples 
             appear to be okay. Talley: "NO3 looks too high, 117-136." No 
             analytical problems noted, footnote no3 uncertain.
118 @ 811db  Footnote no3 uncertain, see 117 comment.
119 @ 910db  Footnote no3 uncertain, see 117 comment.
120 @1015db  Footnote no3 uncertain, see 117 comment.
121 @1225db  Footnote no3 uncertain, see 117 comment.
122 @1427db  Footnote no3 uncertain, see 117 comment.
123 @1622db  Footnote no3 uncertain, see 117 comment.
124 @1822db  Footnote no3 uncertain, see 117 comment.
125 @2024db  Footnote no3 uncertain, see 117 comment.
126 @2224db  Footnote no3 uncertain, see 117 comment.
127 @2432db  Footnote no3 uncertain, see 117 comment.
128 @2637db  Footnote no3 uncertain, see 117 comment.
129 @2831db  Footnote no3 uncertain, see 117 comment.
130 @3038db  Footnote no3 uncertain, see 117 comment.
131 @3296db  Footnote no3 uncertain, see 117 comment.
132 @3542db  Footnote no3 uncertain, see 117 comment.
133 @3793db  Sample Log: Broken valve, nutrients and 
             salinity were drawn. Oxygen was not drawn. Salinity agrees 
             with CTD, nutrients seem to be okay. Footnote no3 uncertain, 
             see 117 comment.
134 @4050db  Sample Log: Broken valve. No samples.
135 @4260db  Footnote no3 uncertain, see 117 comment.
136 @4497db  Footnote no3 uncertain, see 117 comment.

STATION 115

161 @ 3db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 35db   Oxygen and nutrients not drawn per sampling 
             schedule.
163 @ 216db  Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 409db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 613db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @ 815db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1015db  Oxygen and nutrients not drawn per sampling 
             schedule.
168 @2032db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @3069db  Oxygen and nutrients not drawn per sampling 
             schedule.
170 @4115db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4562db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 116

1all         Tsuchiya: "Are the decrease in deep PO4 and NO3 values 
             from Station 114 to 116 real?" Calc and peaks okay. 
             Nutrients: New imidazole buffer, replenish hydrazine. End 
             PO4 stds low, begin stds may be off on chart. Use mean of 
             PO4 standards from Stations 114 and 118. PO4 station 
             comparison much better.
101 @ 0db    Sample Log: Broken lanyard. Sample agree with CTD 
             and with adjoining station.
103 @ 61db   Delta-S is -.1173, appears that salinity was not 
             drawn, and the water is from Station 112 which was the last 
             time the salinity bottle was used. Footnote salinity 
             uncertain, ODF recommends deletion.
108 @ 180db  Sample Log: Slight leak. Samples appear to be 
             okay.
122 @1610db  Sample Log: Slow leak out of tap. Samples 
             appear to be okay.
134 @4059db  Sample Log: Pin bent on valve.
136 @4622db  Sample Log: Valve broken. Salinity and 
             nutrients drawn. Samples appear to be okay. Oxygen was not 
             drawn.

STATION 117

161 @ 2db    Oxygen and nutrients not drawn per sampling 
             schedule.
162 @ 55db   Oxygen and nutrients not drawn per sampling 
             schedule. Sample Log: Air leak. Salinity appears to be okay.
163 @ 55db   Oxygen and nutrients not drawn per sampling 
             schedule.
164 @ 259db  Oxygen and nutrients not drawn per sampling 
             schedule.
165 @ 816db  Oxygen and nutrients not drawn per sampling 
             schedule.
166 @1013db  Oxygen and nutrients not drawn per sampling 
             schedule.
167 @1492db  Sample Log: Air leak, vent not closed tight. 
             Salinity appears to be okay. Oxygen and nutrients not drawn 
             per sampling schedule.
168 @1982db  Oxygen and nutrients not drawn per sampling 
             schedule.
169 @3019db  Oxygen and nutrients not drawn per sampling 
             schedule.
170 @3975db  Oxygen and nutrients not drawn per sampling 
             schedule.
171 @4674db  Oxygen and nutrients not drawn per sampling 
             schedule.

STATION 118

117 @ 708db  Sample Log: Air leak. Oxygen appears a little 
             high compared to CTDO, but agrees with adjoining stations. 
             Footnote bottle leaking, and o2 bad, appears that leaking 
             comment may have effected gas sample.
132 @3711db  Sil appears to be high, peak looks good. 
             Footnote sil uncertain.

STATION 119

1nut         Tsuchiya: "Sil level at the maximum is slightly lower 
             than adjoining station. Is this real?" Calc and peaks okay. 
             Nutrients: Sil channel cleaned with RBS before station.
101 @ 0db    Sample Log: Valve open. Samples agree with 
             adjoining station.
116 @ 810db  Oxygen appears to be high. Footnote o2 
             uncertain.
125 @2372db  Silicate appears to be high. Footnote sil 
             uncertain. Oxygen appears low, footnote o2 uncertain.
131 @3558db  Sample Log: Small leak from spigot. Oxygen 
             agrees with CTDO, other samples appear to be okay, salinity 
             .001 low.

STATION 120

1all         Sample Log: Inner rosette tripped first.
1nut         Tsuchiya: "Verify the alternate decrease and in all 
             deep (>1000m) nutrients from Station 120 (high) to Station 
             123 (low)." Station 122 is only station with comments from 
             nutrient analyst.
101 @2227db  Sample Log: Air leak. Delta-S at 2227db is 
             .0042. Oxygen agrees with CTDO and adjoining station.
108 @3690db  Sample Log: Slight drip. Oxygen is a little 
             high compared with CTDO. Footnote bottle leaking, o2 bad. 
             Appears that gas sample was effected.

STATION 121

1all         Sample Log: O2 delay due to jammed valve in NaI 
             cannula. Oxygen looks reasonable.
1nut         Tsuchiya: "Verify the alternate decrease and in all 
             deep (>1000m) nutrients from Station 120 (high) to Station 
             123 (low)." Station 122 is only station with comments from 
             nutrient analyst.
101 @ 0db    Sample Log: Salinity taken via tritium outflow, 
             nutrient sampled after tritium.
108 @ 162db  Sample Log: Very slight air leak. Samples 
             appear to be okay.
109 @ 193db  Sample Log: Significant air leak. Oxygen and 
             nutrients appear to be okay.
130 @3251db  Sample Log: Lid popped. Samples appear to be 
             okay.

STATION 122

1nut         Tsuchiya: "Verify the alternate decrease and in all 
             deep (>1000m) nutrients from Station 120 (high) to Station 
             123 (low)." Nutrients: Replenish hydrazine, po4 begin 
             baselines odd. PO4 bubble pattern not good,-now pump purge 
             (sp?) Air bar tubing faulty. Restart @2331. PO4 bubble 
             pattern good now.
101 @ 0db    Sample Log: Leaker Samples appear to be okay.
104 @ 119db  Sample Log: Air leaker Samples appear to be 
             okay.
108 @ 180db  Sample Log: Slight leak Samples appear to be 
             okay.
136 @4635db  Sample Log: Water leaker out of spout Samples 
             appear to be okay.

STATION 123

1nut         Tsuchiya: "Verify the alternate decrease and in all 
             deep (>1000m) nutrients from Station 120 (high) to Station 
             123 (low)." Station 122 is only station with comments from 
             nutrient analyst.
101 @ 0db    Sample Log: Air leak Samples appear to be okay.
110 @ 262db  Sample Log: Slight air leak Oxygen appears a 
             little high compared to adjoining station, but agrees with 
             CTDO. Footnote bottle leaking and o2 uncertain. Appears that 
             gas sample was effected.
136 @4582db  Sample Log: Air leak Oxygen a little low 
             compared with CTDO, other samples appear to be okay. 
             Footnote o2 bad, footnote bottle leaking.




C.4.  LARGE VOLUME SAMPLING: P17C  31WTTUNES_1 (TUNES 1)
      (Robert M. Key, PI)
      17 July 1995

                                                              DATA SUBMITTED BY:
                                             Scripps Institution of Oceanography
                                                     Oceanographic Data Facility


DESCRIPTION OF MEASUREMENT TECHNIQUES AND CALIBRATIONS

Large Volume Sampling (LVS) was performed on this expedition.  These
commonly referred to as Gerard casts were carried out with ~270 liter
stainless steel Gerard barrels on which were mounted 2-liter Niskin bottles
(Piggyback bottles) with reversing thermometers.

There were 17 large volume stations, with at least one deep cast (2500db to
the bottom), and either or both an intermediate (1000db to 2500db) and/or a
shallow cast (surface to 1000db). There were 21 casts total, 4 of which
were redeployments to complete the complement of 9 levels. The cast was
relowered if the complement of 9 levels was not achieved due to pretrips or
failure of one Gerard barrel releasing it's messenger thereby tripping the
rest of the string of barrels.  The Gerard barrel platform, as set up in
port prior to the cruise, did not allow enough clearance for barrel during
deployment & recovery.  The Chief Engineer cut the platform loose and
rewelded it to the deck about one foot forward.  The spring-loaded
trapping-pin was no longer usable so a chain was shackled to one forward
corner of the platform, passed aft of the wire then hooked to the other
forward corner to hold the trawl wire in the platform "V" while the barrels
were being attached and detached.  Limited fantail space and the low trawl
wire lead required that the crane work over the wire to move barrels from
racks to near the centerline just forward of the platform, then the barrel
was unhooked and the crane moved to the other side of the wire and rehooked
to move the barrel to the attachment position. This procedure was reversed
for recovery.  Working Gerards off the stern went well in good weather but,
as expected, pitching in moderate seas (15-20 knots wind) caused tripping
problems. Slowing down the lowering rate to less than 50 meters/minute
seemed to help.

Samples for salinity, silicate and 14C were obtained from the Gerard
barrels; samples for salinity were drawn from the piggyback bottles.  The
salinity samples from the piggyback bottle were used for comparison with
the Gerard barrel salinities to verify the integrity of the Gerard sample.
The identifiers of the sample containers and the numbers of the ODF or
Piggyback samplers from which the samples were drawn were recorded on the
Sample Log sheet.  Normal ODF sampling practice is to open the drain valve
before opening the air vent to see if water escapes, indicating the
presence of a small air leak in the sampler.  This observation ("air
leak"), and other comments ("lanyard caught in lid", "valve left open",
etc.) which may indicate some doubt about the integrity of the water
samples were also noted on the Sample Log sheets.  These comments are
included in this documentation with investigative comments and results.

The discrete hydrographic data were entered into the shipboard data system
and processed as the analyses were completed.  The bottle data were brought
to a usable, though not final, state at sea.  ODF data checking procedures
included verification that the sample was assigned to the correct depth.
This was accomplished by checking the raw data sheets, which included the
raw data value and the water sample bottle, versus the sample log sheets.
The salinity and nutrient data were compared by ODF with those from
adjacent stations.  Any comments regarding the water samples were
investigated.  The raw data computer files were also checked for entry
errors that could have been made on the station number, bottle number
and/or sample container number.  The salinity and nutrient values were
transmitted from PC's attached to either the salinometer or Autoanalyzer
system.

Investigation of data included comparison of piggyback salinities versus
Gerard salinities, and review of data plots of the station rosette data
profile.  If any problem was indicated, the data value was flagged.  The
Quality Comments includes comments regarding missing samples and
investigative remarks for comments made on the Sample Log sheets, as well
as all flagged (WOCE coded) data values other than 2, an acceptable
measurement.

The WOCE codes were assigned to the water data using the criteria:

code 1 =  Sample for this measurement was drawn from water bottle, but
          results of analysis not yet received.

code 2 =  Acceptable measurement.

code 3 =  Questionable measurement.  Does not fit station profile or
          adjoining station comparisons. No notes from analyst indicating a
          problem.  Datum could be real, but the decision as to whether it
          is acceptable will be made by a scientist rather than ODF's
          technicians.

code 4 =  Bad measurement.  Does not fit station profile and/or adjoining
          station comparisons.  There are analytical notes indicating a
          problem, but data values are reported.  ODF recommends deletion
          of these data values.  Analytical notes for salinity may include
          large differences between the piggyback and Gerard sample.
          Sampling errors are also coded 4.

code 9 =  Sample for this measurement not drawn.

Quality flags assigned to parameter BTLNBR (bottle number) as defined in
the WOCE Operations manual are further clarified as follows:

code 4 =  If the bottle tripped at a different level than planned, ODF
          assigned it a code 4.  If there is a 4 code on the bottle, and 2
          codes on the salinity, oxygen and nutrients then the pressure
          assignment was probably correct.

code 3 =  An air leak large enough to produce an observable effect on a
          sample is identified by a 3 code on the bottle and 4 code on the
          oxygen.  (Small air leaks may have no observable effect, or may
          only affect gas samples).

The following table shows the number of ODF samples drawn and the number of
times each WOCE sample code was assigned.


Large Volume Samples
Stations 17-121                                                        

             | Reported |            WHP Quality Codes
             | levels   | 1 |   2 | 3 |  4 |  5 | 6 | 7 | 8 |   9
      -------|----------|---|-----|---|----|----|---|---|---|----
      BTLNBR |    306   | 0 | 287 | 2 | 12 |  0 | 0 | 0 | 0 |   5
      SALNTY |    300   | 0 | 288 | 2 | 10 |  1 | 0 | 0 | 0 |   5
      SILCAT |    152   | 0 | 150 | 0 |  2 |  0 | 0 | 0 | 0 | 154
      NITRAT |      0   | 0 |   0 | 0 |  0 |  0 | 0 | 0 | 0 | 306
      NITRIT |      0   | 0 |   0 | 0 |  0 |  0 | 0 | 0 | 0 | 306
      PHSPHT |      9   | 0 |   0 | 0 |  9 |  0 | 0 | 0 | 0 | 297
      REVPRS |    306   | 0 | 306 | 0 |  0 |  0 | 0 | 0 | 0 |   0
      REVTMP |    296   | 0 | 292 | 0 |  4 | 10 | 0 | 0 | 0 |   0


1.  Pressure and Temperature

LVS pressures and temperatures were calculated from deep-sea reversing
thermometer (DSRT) readings.  Each DSRT rack normally held 2 protected
(temperature) thermometers and 1 unprotected (pressure) thermometer.
Thermometers were read by two people, each attempting to read a precision
equal to one tenth of the thermometer etching interval.  Thus, a
thermometer etched at 0.05 degree intervals would be read to the nearest
0.005 degrees.

Each temperature value reported on the LVS casts is calculated from the
average of four readings provided both protected thermometers function
normally.  The pressure is verified by comparison with the calculation of
pressure determined by wireout.  The pressure from the thermometer is
fitted by a polynomial equation which incorporates the wireout and wire
angle.

Calibration of the thermometers are performed in ODF's calibration facility
depending on the age of the thermometer and not more than two years of the
expedition.

The temperatures are based on the International Temperature Scale of 1990.


2.  Salinity Analysis

Salinity samples were drawn into 200 ml Kimax high alumina borosilicate
bottles after 3 rinses, and were sealed with custom-made plastic insert
thimbles and Nalgene screw caps.  This assembly provides very low container
dissolution and sample evaporation.  As loose inserts were found, they were
replaced to ensure a continued airtight seal.  Salinity was determined
after a box of samples had equilibrated to laboratory temperature, usually
within 8-12 hours of collection. The draw time and equilibration time, as
well as per-sample analysis time and temperature were logged.

A single Guildline Autosal Model 8400A salinometer (Serial Number 57-396)
located in a temperature-controlled laboratory was used to measure
salinities. The salinometer was modified by ODF and contained interfaces
for computer-aided measurement. A computer (PC) prompted the analyst for
control functions (changing sample, flushing) while it made continuous
measurements and logged results.  The salinometer cell was flushed until
successive readings met software criteria for consistency, then two
successive measurements were made and averaged for a final result.

The salinometer was standardized for each cast with IAPSO Standard Seawater
(SSW) Batch P-120, using at least one fresh vial per cast.  The estimated
accuracy of bottle salinities run at sea is usually better than 0.002 PSU
relative to the particular Standard Seawater batch used.  PSS-78 salinity
(UNESCO 1981) was then calculated for each sample from the measured
conductivity ratios, and the results merged with the cruise database.

300 salinity measurements were made and 18 vials of standard water were
used.  The temperature stability of the laboratory used to make the
measurements was good.  There were some problems with lab temperature
control throughout cruise; the Autosal bath temperature was adjusted
accordingly.  Salinities were generally considered good for the expedition
despite the lab temperature problem.  Salinity samples were analyzed for
the Large Volume casts from both the piggyback bottle and the Gerard
barrel.


3.  Nutrient Analysis

Nutrient samples were drawn into 45 ml high density polypropylene, narrow
mouth, screw-capped centrifuge tubes which were rinsed three times before
filling.  Standardizations were performed at the beginning and end of each
group of analyses (one station, usually 18 samples) with a set of an
intermediate concentration standard prepared for each run from secondary
standards.  These secondary standards were in turn prepared aboard ship by
dilution from dry, pre-weighed primary standards.  Sets of 5-6 different
concentrations of shipboard standards were analyzed periodically to
determine the deviation from linearity as a function of concentration for
each nutrient.

Nutrient analyses (phosphate, silicate, nitrate and nitrite) were performed
on an ODF-modified 4 channel Technicon AutoAnalyzer II, generally within
one hour of the cast.  However, on LVS cast, samples for the Gerard barrels
were analyzed for silicate only as an added check (with salinity) on barrel
sample integrity.  Occasionally some samples were refrigerated at 2 to 6
degree C for a maximum of 4 hours.  The methods used are described by
Gordon et al. (1992), Atlas et al. (1971), and Hager et al. (1972).

All peaks were logged manually, and all the runs were re-read to check for
possible reading errors.

Silicate is analyzed using the technique of Armstrong et al.  (Armstrong
1967).  Ammonium molybdate is added to a seawater sample to produce
silicomolybdic acid which is then reduced to silicomolybdous acid (a blue
compound) following the addition of stannous chloride. Tartaric acid is
also added to impede PO4 contamination.  The sample is passed through a 15
mm flowcell and the absorbence measured at 820nm. ODF's methodology is
known to be non-linear at high silicate concentrations (>120 uM); a
correction for this non-linearity is applied in ODF's software.

Modifications of the Armstrong et al.  (1967) techniques for nitrate and
nitrite analysis are also used.  The seawater sample for nitrate analysis
is passed through a cadmium column where the nitrate is reduced to nitrite.
Sulfanilamide is introduced, reacting with the nitrite, then
N-(1-naphthyl)ethylenediamine dihydrochloride which couples to form a red
azo dye. The reaction product is then passed through a 15 mm flowcell and
the absorbence measured at 540 nm.  The same technique is employed for
nitrite analysis, except the cadmium column is not present, and a 50 mm
flowcell is used.

Phosphate is analyzed using a modification of the Bernhardt and Wilhelms
(1967) technique. Ammonium molybdate is added to the sample to produce
phosphomolybdic acid, then reduced to phosphomolybdous acid (a blue
compound) following the addition of dihydrazine sulfate. The reaction
product is heated to 55 degree C to enhance color development, then passed
through a 50 mm flowcell and the absorbence measured at 820 nm.

Nutrients, reported in micromoles per kilogram, were converted from
micromoles per liter by dividing by sample density calculated at zero
pressure, in-situ salinity, and an assumed laboratory temperature of 25
degree C.

Na2SiF6, the silicate primary standard, is obtained from Fluka Chemical
Company and Fischer Scientific and is reported by the suppliers to be >98%
pure.  Primary standards for nitrate KNO3, nitrite NaNO2, and phosphate
KH2PO4, are obtained from Johnson Matthey Chemical Co. and the supplier
reports purities of 99.999%, 97%, and 99.999%, respectively.

152 nutrient (Silicate) analyses were performed. No major problems were
encountered with the measurements.



REFERENCES AND UNCITED SUPPORTING DOCUMENTATION

Armstrong, F. A. J., C. R. Stearns, and J. D. H. Strickland, 1967.  The
     measurement of upwelling and subsequent biological processes by means
     of the Technicon Autoanalyzer and associated equipment, Deep-Sea
     Research, 1144, 381-389.

Atlas, E. L., S. W. Hager, L. I. Gordon and P. K. Park, 1971. A Practical
     Manual for Use of the Technicon(R) AutoAnalyzer(R) in Seawater
     Nutrient Analyses; Revised. Technical Report 215, Reference 71-22.
     Oregon State University, Department of Oceanography. 49 pp.

Bernhardt, H. and A. Wilhelms, 1967.  The continuous determination of low
     level iron, soluble phosphate and total phosphate with the
     AutoAnalyzer, Technicon Symposia, Volume I, 385-389.

Brewer, P. G. and G. T. F. Wong, 1974. The determination and distribution
     of iodate in South Atlantic waters.  Journal of Marine Research,
     3322,1:25-36.

Bryden, H. L., 1973. New Polynomials for Thermal Expansion, Adiabatic
     Temperature Gradient, Deep-Sea Research, 2200, 401-408.

Carpenter, J. H., 1965. The Chesapeake Bay Institute technique for the
     Winkler dissolved oxygen method, Limnology and Oceanography, 1100,
     141-143.

Carter, D. J. T., 1980 (Third Edition).  Echo-Sounding Correction Tables,
     Hydrographic Department, Ministry of Defence, Taunton Somerset.

Chen, C.-T. and F. J. Millero, 1977. Speed of sound in seawater at high
     pressures.  Journal Acoustical Society of America, 6622, No. 5,
     1129-1135.

Culberson, C. H., Williams, R. T., et al, August, 1991. A comparison of
     methods for the determination of dissolved oxygen in seawater, WHP
     Office Report WHPO 91-2.

Fofonoff, N. P., 1977. Computation of Potential Temperature of Seawater for
     an Arbitrary Reference Pressure.  Deep-Sea Research, 2244, 489-491.

Fofonoff, N. P. and R. C. Millard, 1983. Algorithms for Computation of
     Fundamental Properties of Seawater. UNESCO Report No. 44, 15-24.

Gordon, L. I., Jennings, Joe C. Jr, Ross, Andrew A., Krest, James M., 1992.
     A suggested Protocol for Continuous Flow Automated Analysis of
     Seawater Nutrients in the WOCE Hydrographic Program and the Joint
     Global Ocean Fluxes Study. OSU College of Oceanography Descr. Chem Oc.
     Grp. Tech Rpt 92-1.

Hager, S. W., E. L. Atlas, L. D. Gordon, A. W. Mantyla, and P. K. Park,
     1972.  A comparison at sea of manual and autoanalyzer analyses of
     phosphate, nitrate, and silicate.  Limnology and Oceanography, 1177,
     931-937.

Lewis, E. L., 1980. The Practical Salinity Scale 1978 and Its Antecedents.
     IEEE Journal of Oceanographic Engineering, OE-5, 3-8.

Mantyla, A. W., 1982-1983. Private correspondence.

Millero, F. J., C.-T. Chen, A. Bradshaw and K. Schleicher, 1980.  A New
     High Pressure Equation of State for Seawater.  Deep-Sea Research, 2277AA,
     255-264.

Saunders, P. M., 1981. Practical Conversion of Pressure to Depth.  Journal
     of Physical Oceanography, 1111, 573-574.

Sverdrup, H. U., M. W. Johnson, and R. H. Fleming, 1942.  The Oceans, Their
     Physics, Chemistry and General Biology, Prentice-Hall, Inc., Englewood
     Cliff, N.J.

UNESCO, 1981. Background papers and supporting data on the Practical
     Salinity Scale, 1978.  UNESCO Technical Papers in Marine Science, No.
     37, 144 p.


Quality Comments

Remarks for  missing samples, and WOCE codes other than 2 from TUNES Leg 1
WOCE P17C Large Volume Samples.  Investigation of data may include
comparison of bottle salinity and silicate data from piggyback and Gerard
with CTD cast data, review of data plots of the station profile and
adjoining stations, and rereading of charts (i.e., nutrients).  Comments
from the Sample Logs and the results of ODF's investigations are included
in this report.  Units stated in these comments are micromoles per liter
for Silicate unless otherwise noted.  The first number before the comment
is the cast number (CASTNO) times 100 plus the bottle number (BTLNBR). PB
refers to the bottle that is attached to the Gerard.

Station 017

548 @ 497db    Sample log: "Didn't close" Lanyard stuck.  No water sample
               or therm readings. GB93 at this level (497db) has good
               salinity and SIL compared to other samples this station.

593 @ 497db    Gerard is acceptable, no temperature. See PB (48) comment.

388 @1992db    Sample log: "tripped but messenger hung" Relowered bottom 4
               barrels as cast 4.  PB (45).

446 @2249db    Sample log: "Air leak" N-G -.001 at 2248db.  Gerard (89) is
               okay.

489 @2249db    Sample log: "Air vent not tight. messenger hung - tripping
               wire loose" N-G -.001 at 2249db. Gerard SIL also ok.  Gerard
               is okay, PB (46).  Bottom 3 barrels tripped as cast 5 with
               Terminal Reading 762m (wire out when GB89 taken off wire).

141 @3155db    Delta-S(PB-G) at 3155db is 0.007, salinity is 34.665.
               Footnote salinity bad.  Gerard (83) is okay.

183 @3156db    Gerard is okay, PB (41).

142 @3660db    N-G .021 at 3660db. See 185. PB salinity calc ok. No other
               samples from Niskin.  Footnote salinity bad. Gerard (85) is
               acceptable.

185 @3660db    Sample log: "drain valve loose" N-G -.021 at 3660db.  Gerard
               salinity, silicate & phosphate match profile from other
               samples this station. PB (142) appears low. Gerard is
               acceptable, PB (42) may have leaked.

146 @4419db    Delta-S(PB-G) at 4419db is 0.002, salinity is 34.677.
               Gerard (89) is acceptable.

189 @4419db    Sample log: "air vent loose" N-G .002 at 4419db. PO4 & SIL
               from Gerard also look good.  Gerard is acceptable, PB (46).

148 @4931db    Sample log: "bottom end cap hung up" No water samples.

193 @4931db    No check sample from PB. See 148.  Gerard salinity,
               phosphate & silicate match profile from other samples this
               station.

Station 026

345 @ 175db    Sample log: "Didn't close."  No temperature. Gerard (88) is
               acceptable.

388 @ 176db    No temperature, PB (45) did not trip.  Gerard probably okay,
               salinity agrees with rosette data.  Silicate is ~2.0 high
               vs. rosette data.

343 @ 542db    Delta-S(PB-G) at 542db is 0.004, salinity is 34.030.  Gerard
               (85) is probably okay. PB salinity is high compared with
               rosette data.

385 @ 543db    Gerard is probably okay, PB (43).  Silicate agrees with
               rosette data.

344 @ 794db    Delta-S(PB-G) at 794db is 0.005, salinity is 34.282.  Gerard
               (87) is probably okay. PB salinity is high compared with
               rosette data.

387 @ 795db    Gerard is okay, PB (44).  Silicate agrees with rosette data.

342 @1091db    Sample log: "Broken bottom block."  Gerard (84) is
               acceptable.  Delta-S(PB-G) at 1091db is 0.002, salinity is
               34.449.

142 @2997db    Delta-S(PB-G) at 2997db is -0.007, salinity is 34.657.
               Footnote salinity bad, could be drawing error.  Gerard (84)
               is acceptable.

146 @3999db    Delta-S(PB-G) at 3999db is -0.003, salinity is 34.679.
               Gerard (89) is okay. PB salinity is low compared with
               rosette data.

148 @4506db    Sample log: "Spigot was pushed in, little water in niskin"
               N-G -.003 at 4509db.  Gerard (93) is acceptable.  Delta-
               S(PB-G) at 4506db is -0.003, salinity is 34.681.

193 @4506db    Gerard is acceptable, PB (48).

149 @4761db    Delta-S(PB-G) at 4761db is 0.006, salinity is 34.683.  PI to
               decide integrity of Gerard (94).

194 @4761db    Salinity is low compared to rosette cast, too.  Silicate is
               low compared with adjoining rosette stations, but is
               acceptable. PB (49).  Footnote salinity bad.  PI to decide
               integrity of Gerard.

Station 034

Cast 1         All samples accounted for.  C-14 extraction only.

183 @2582db    Sample log: "Needs pillow block."  PB (42).

150 @3793db    Sample log: "Replaced Niskin 46 with 50 - broken upper
               block."  Delta-S(PB-G) at 3793db is 0.009, salinity is
               34.680.  Gerard (89).

148 @4405db    Delta-S(PB-G) at 4405db is 0.004, salinity is 34.683.
               Gerard (93).

193 @4406db    Sample log: "Tightened niskin trip."  PB (48).

Station 046

183 @3453db    Sample log: "Didn't latch - O-ring off center."  Salinity
               agrees with rosette and PB salinity, silicate agrees with
               rosette data. Let PI decide on integrity of  Gerard.  PB
               (42).

143 @3703db    Temperature is ~0.09 high, salinity agrees with Gerard and
               rosette data. Footnote temperature bad.  Gerard (84) is
               acceptable.

184 @3703db    Gerard is acceptable. See PB (43) temperature comment.
               Footnote temperature bad.

145 @4209db    No sample or temperature, Gerard (87) also had no sample.

187 @4209db    Sample log: "Didn't trip - no tripping pin."  No sample or
               temperature, PB (45) also had no sample.

189 @4465db    Sample log: "Closed but didn't latch."  Salinity agrees with
               rosette and PB salinity, silicate agrees with rosette data.
               Let PI decide on integrity of Gerard.  PB (50).

Station 057

342 @1240db    Sample log: "Spigot pushed in."  Gerard (83) is acceptable.

383 @1241db    Sample log: "Replaced lid o-ring but still a very tight fit.
               Did not latch - swap with 88 next time."  Gerard is
               acceptable, PB (42).

350 @1511db    Gerard (89) is acceptable within 20db of reassigned
               pressure.

389 @1511db    Sample log: "Lid closed @ ~1570 by salt, Si, and T."
               Thermometric pressure, both Niskin (50) & Gerard salinities
               (89), and Gerard silicate indicate barrel closed at about
               1510db instead of the intended depth of 2242db.  The double
               ping came on time and all samples below were ok so the
               messenger released properly but the Gerard lid closed early
               or late.  Footnote bottle did not trip correctly. PB (50).
               Samples are good within 20 db of reassigned pressure.

344 @1741db    Sample log: "Came up no therm rack?"  Gerard (85) is
               acceptable.

385 @1742db    Gerard is acceptable, no temperature, see PB (44) comment.

142 @3301db    Delta-S(PB-G) at 3301db is 0.014, salinity is 34.672.
               Gerard (83) leaked.

183 @3301db    Sample log: "Didn't latch - o-ring again same as before."
               Delta-S(PB-G) at 3301db is 0.014, salinity is 34.672.  Data
               show leak on Gerard 83.  Footnote bottle leaking, samples
               bad. PB (42).

145 @3981db    Gerard (87) is acceptable. Temperature is ~0.04 high.
               Footnote temperature bad.

187 @3982db    Gerard is acceptable. Footnote temperature bad.  PB (45).

Station 066

343 @1420db    Delta-S(PB-G) at 1420db is 0.02, salinity is 34.585.  Gerard
               salinity is low.  Could be a drawing error.  Let PI decide
               integrity of Gerard (85).

385 @1420db    Delta-S(PB-G) at 1420db is 0.02, salinity is 34.585.  Gerard
               salinity is low. Silicate agrees with rosette cast. Could be
               a drawing error.  Footnote salinity bad.  Let PI decide
               integrity of Gerard (85).  PB (43).

387 @1658db    Sample log:  "Messenger not released."  Gerard is
               acceptable, PB (44).  The remainder of the profile was done
               as Cast 4.

149 @4935db    Delta-S(PB-G) at 4935db is 0.004, salinity is 34.693.
               Gerard (94) may have leaked.  Gerard salinity is low,
               silicate looks reasonable.  Suspect there was a leak, let PI
               decide.

194 @4936db    Sample log: "Air vent open on return. Was definitely closed
               when deployed."  Gerard salinity is low, silicate looks
               reasonable.  Suspect there was a leak, let PI decide.
               Footnote bottle leaking, salinity bad.  PB (49).

Station 076

Cast 1         Sample log: "Cast nominal. Thermometer malfunction."

389 @1588db    Sample log: "Therm rack 6 reversed on deck."  Temperature is
               lost.  Gerard salinity and silicate agree with rosette data.
               Gerard is acceptable, PB (50).

350 @1588db    Temperature is lost.  Gerard salinity and silicate agree
               with rosette data.  Gerard (89) is acceptable.

Station 098

150 @ 617db    Delta-S(PB-G) at 617db is -0.014, salinity is 34.577.
               Thermometric Pressure 617 vs intended depth 3370db.  Water
               samples also from about 617db.  Footnote bottle pretripped
               and samples bad.  Gerard (88) appears to have leaked.

188 @ 617db    Sample Log: "Bad o-ring?  Would not pressurize; opened and
               reclosed, o-ring damaged."  Thermometric Pressure 617 vs
               intended depth 3370db.  Water samples also from about 617db.
               Lid o-ring cut, difficult to open lid.  Used 617 db as
               accepted pressure with water samples as is.  Footnote bottle
               did not trip correctly, samples bad.  PB (50).

393 @1894db    Delta-S(PB-G) at 1893db is -0.0592, salinity is 34.639.
               Salinity too high, but sil reasonable.  Footnote salinity
               bad.

145 @3117db    Delta-S(PB-G) at 3117db is -0.011, salinity is 34.677.  PI
               to decide integrity of Gerard (87).

187 @3118db    Delta-S(PB-G) at 3117db is -0.011, salinity is 34.677.
               Gerard salinity is high, SiO3 agrees with rosette data.
               Footnote salinity bad.  Have PI decide the integrity of
               Gerard samples.  PB (45).

Station 121

289 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

290 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

293 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

294 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

350 @1921db    Gerard (89) is acceptable at reassigned pressure.

389 @1921db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (50).

347 @2220db    Gerard (90) is acceptable at reassigned pressure.

390 @2220db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (47).

348 @2534db    Delta-S(PB-G) at 2534db is -0.002, salinity is 34.664.
               Gerard (93) is acceptable at reassigned pressure.

393 @2535db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (48).

281 @2673db    Salinity bottle was broken before analysis could be
               performed.  Salinity lost.  Silicate is high compared to
               rosette data, but agrees with silicate from other Gerard
               casts (which are also higher than rosette data).  Suspect
               Gerard is acceptable.  PB (41).

349 @2864db    Delta-S(PB-G) at 2864db is 0.002, salinity is 34.675.
               Gerard (94) is acceptable at reassigned pressure.

394 @2864db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (49).

242 @2938db    Gerard (84) is acceptable, PB salinity is low.  Footnote
               salinity questionable.  Delta-S(PB-G) at 2938db is -0.004,
               salinity is 34.670.

445 @3282db    Sample Log: "Valve open."  Gerard (87) is acceptable.
               Delta-S(PB-G) at 3282db is -0.002, salinity is 34.680.



D.  WHPO SUMMARY

Several data files are associated with this report. They are the p17c.sum, 
p17c.hyd, p17c.csl and *.wct files. The p17c.sum file contains a summary of the 
location, time, type of parameters sampled, and other pertient information 
regarding each hydrographic station. The p17c.hyd file contains the bottle data. 
The *.wct files are the ctd data for each station. The *.wct files are zipped 
into one file called p17cwct.zip. The p17c.csl file is a listing of ctd and 
calculated values at standard levels.

The following is a description of how the standard levels and calculated values 
were derived for the p17c.csl file:

Salinity, Temperature and Pressure: These three values were smoothed from the 
individual CTD files over the N uniformly increasing pressure levels using the 
following binomial filter-

          t(j) = 0.25ti(j-1) + 0.5ti(j) + 0.25ti(j+1) j=2....N-1

When a pressure level is represented in the *.csl file that is not contained 
within the ctd values, the value was linearly interpolated to the desired level 
after applying the binomial filtering.

Sigma-theta(SIG-TH:KG/M3), Sigma-2 (SIG-2: KG/M3), and Sigma-4(SIG-4: KG/M3): 
These values are calculated using the practical salinity scale (PSS-78) and the 
international equation of state for seawater (EOS-80) as described in the Unesco 
publication 44 at reference pressures of the surface for SIG-TH; 2000 dbars for 
Sigma-2; and 4000 dbars for Sigma-4.
Gradient Potential Temperature (GRD-PT: C/DB 10-3) is calculated as the least 
squares slope between two levels, where the standard level is the center of the 
interval. The interval being the smallest of the two differences between the 
standard level and the two closest values. The slope is first determined using 
CTD temperature and then the adiabatic lapse rate is subtracted to obtain the 
gradient potential temperature. Equations and Fortran routines are described in 
Unesco publication 44.

Gradient Salinity (GRD-S: 1/DB 10-3) is calculated as the least squares slope 
between two levels, where the standard level is the center of the standard level 
and the two closes values. Equations and Fortran routines are described in 
Unesco publication 44.

Potential Vorticity (POT-V: 1/ms 10-11) is calculated as the vertical component 
ignoring contributions due to relative vorticity, i.e. pv=fN2/g, where f is the 
coriolius parameter, N is the bouyancy frequency (data expressed as radius/sec), 
and g is the local acceleration of gravity. 

Bouyancy Frequency (B-V: cph) is calculated using the adiabatic leveling method, 
Fofonoff (1985) and Millard, Owens and Fofonoff (1990). Equations and Fortran 
routines are described in Unesco publication 44.

Potential Energy (PE: J/M2: 10-5) and Dynamic Height (DYN-HT: M) are calculated 
by integrating from 0 to the level of interest. Equations and Fortran routines 
are described in Unesco publication, Processing of Oceanographic station data, 
1991.

Neutral Density (GAMMA-N: KG/M3) is calculated with the program GAMMA-N (Jackett 
and McDougall) version 1.3 Nov. 94. 

    


E.  DATA QUALITY EVALUATIONS

E.1  DQE OF CTD DATA FOR TUNES LEG 1 WOCE P17C
     (Robert Millard)
     January 26, 1995

GENERAL:

The data quality of the CTD data of the individual 2-decibar CTD profiles and 
the CTD salinity and oxygen found in the water sample file are examined. The 
individual 2 decibar profiles were checked for glitches in temperature, salinity 
and oxygen by comparing individual profiles against one of two average profiles; 
the first average is of the East-West section and involving stations 6 through 
17 and the second station grouping is the North-South section involving stations 
18 through 123. The average profiles include standard deviation of temperature, 
salinity and oxygen which when scaled (default edit factor is 5.0 times the 
standard deviation) become the edit criteria for flagging questionable data. The 
stability parameter is also computed for observations within a profile and 
values less than a stability value (E = -5.0e-4 per meter) are also flagged. The 
stability edit criteria flags density inversions greater than .015 Kg/M3 per 
decibar. The screening of the entire 2 decibar data set against these edit 
criteria indicated the data to be free of spurious bad values in temperature, 
salinity and oxygen.

The CTD salinity (conductivity) and oxygen calibrations are checked using the 
water sample data file P17C.DQE. In comparing the CTD and water sample salinity 
and oxygen in the water sample file, only those data having a quality flag 
indicating a good measurement (ie values of 2) were used. The salinity and 
oxygen differences (CTD-Water Sample) are plotted in histogram form with 
salinity in figure 1 and oxygen figure 2. Salinity and oxygen differences are 
plotted versus station number in figures 3 and 4 and versus pressure in figures 
5a, 5b and 6. The plots versus pressure use expanded scales which don't show the 
extreme differences that occur in the upper few hundred decibars. The maximum 
salinity difference is .16 psu while the maximum difference of oxygen is 53.6 
micromoles/kg.

The deep water sample salinity and oxygen differences are also examined 
separately by further screening the good data (ie. quality value ="2") to 
exclude potential temperature values greater than 2.5 C. These comparisons are 
displayed in histograms of salinity and oxygen differences (figures 7 & 8) plus 
plots of the salinity and oxygen differences versus station number in figures 9 
and 10 respectively. The CTD salinity and oxygen of the water sample file are 
found to be well matched to the water samples over the cruise.


DETAILS:

EVALUATION OF CTD CALIBRATIONS TO WATER SAMPLES:

SALINITY:
The histogram of salinity differences for all depths (figure 1) shows a symetric 
distribution. The standard deviation is fairly large at 0.010 psu but 149 of a 
total of 3723 good salinity values that have a difference exceeding ±.02 psu. 
All of these large differences are shallower than 320 decibars and if excluded 
decrease the standard deviation to .0041 psu. The histogram of salinity 
differences for potential temperatures below 2.5 C (figure 7) has a mean 
difference of -0.00015 psu and a much smaller standard deviation of .0016 psu. 
The histogram of deep salinity differences is fairly normally distributed with a 
scatter that probably represents the uncertainty of the water sample salinity 
data. All good values of the salinity differences are plotted versus station in 
figure 3 and show no station dependent variations over the cruise. The 
distribution of salinity differences versus pressure (figure 5a) hints that the 
CTD salinity has a trend towards slightly saltier values as depth increases. The 
salinity differences below 2.5 C are displayed on an expanded scale in figure 5b 
to make this slight pressure dependence more obvious. A least squares regression 
line found on figure 5b indicates the pressure dependence is about .001 psu per 
1500 decibars. The plot of deep salinity differences versus station shown in 
figure 9 suggests a small station dependent variations of about ±0.001 psu in 
several 10 to 20 station groups. For example, the section of data between 
stations 43 and 57 appears to show the CTD salinity slightly salty at 43 and 
drifts to a slightly fresh value by station 57. An expanded scale plot is made 
for stations 43 to 57 (figure 11) that better shows the station drift as does 
the line indicating the least squares fit. This drift is reinforced by plots of 
potential temperature versus salinity for the two four station groups plots 
including stations 43 and 57. Figure 12 has salinities of stations 42, 43, 44, 
and 45 for both the 2 decibar CTD and water sample files. The water sample 
salinities (squares) are fresher [below 1.3 C) than CTD salinities of either the 
2 decibar (down) or water sample file CTD salinity (up). Figure 13 showns 
stations 54, 55, 56, and 57 nown the water sample salinities (squares) on the 
salty side of the CTD salts (both down and up). The magnitude of these salinity 
drifts are small (±0.001 psu) but they are systematic. Figure 9 shows a hint of 
this behavior in two other stations groups (stations 60 through 78) and perhaps 
stations 20 through 30 but no close examination was made.

OXYGEN:
The distribution of oxygen differences at all depths shown in the histogram of 
figure 2 indicates a well behaved fairly random distribution. The standard 
deviation of oxygen differences for all levels is 4.47 micromole/kg. The 
histogram of oxygen differences for potential temperatures below 2.5 C is 
tighter with a standard deviation of 1.12 Um/kg. The plot of oxygen differences 
for all good oxygens versus station in figure 4 has no suggestion of a station 
dependence. The largest oxygen difference is 53.6 micromoles/kg and 63 oxygen 
differences of a total of 3220 good oxygen comparisons exceed 15 microMoles/kg. 
All are shallower than 455 decibars. The plot of oxygen differences versus 
pressure (figure 6) shows that the CTD oxygen differences are well behaved in 
the vertical. Figure 6 uses expanded scales that excludes oxygen differences 
greater than ±15 micromoles/kg. The distribution of deep oxygen differences 
versus station in figure 10 are devoid of any station dependence trends. The CTD 
oxygen calibrations for this data set are excellent.

Comparison 2-dbar stations to Mean profile: Stations 1 to 17- East-West
The data quality of the 2 decibar CTD data for the East-West section compares 
well to the mean profile. A few of the shallow oxygen levels of the coastal 
stations (1 and 2) are flagged as questionable even with a large (10 standard 
deviation) edit criteria. A check of the water sample data indicates that these 
oxygens are fine and the problem resides with using the East-West mean profile 
in the coastal region.

Comparison 2-dbar stations to Mean profile Sta 18 to 123: North-South section
Comparing the individual salinity, temperature and oxygen values against an edit 
criteria of 5 standard deviations from the mean profile of stations 18 through 
123, no data errors were incountered for any of the station files listed below. 
The individual profiles were also tested for density instabilities using a 
minimum stability parameter value of -1.0 E-5. This amounts to a density 
inversion of .015 kg/M3 per decibar.

SUMMARY:
On the whole, WOCE section P17C represents a model CTD data set. The Tunes leg 1 
CTD data set is well calibrated in salinity at the ±0.001 psu level and the CTD 
oxygen calibration is excellent. There is a suggestion of a pressure dependence 
to the CTD salinity (conductivity) with the CTD becoming increasingly salty with 
increasing pressure by roughly .001 psu per 1500 decibars which should be 
examined. This is about the magnitude of the conductivity cell pressure 
deformation correction. There is a hint of a drift in the salinity differences 
below 2.5 C that should be checked out. The 2 decibar profiles are free of 
spurious data gliches. The Chief Scientists cruise report has a very useful 
discussion of the CTD instrument calibration results. There is mention of a 
follow up report that ODF is writing on the CTD calibrations but I have not seen 
it.

Listing of results from a check for spurious data in 2 decibar station files

  File name  Pmax    E_Tot  T_err  S_err  O2_err     E_err  Sd_fact    E_Min  
001D1.WCT     552.0     19      0      0     19      0  7.00   -0.50E-03    0
002D1.WCT     912.0     14      0      0     14      0  7.00   -0.50E-03    0
003D1.WCT    1476.0      0      0      0      0      0  7.00   -0.50E-03    0
004D1.WCT    2464.0      0      0      0      0      0  7.00   -0.50E-03    0
005D1.WCT    3448.0      0      0      0      0      0  7.00   -0.50E-03    0
006D1.WCT    4074.0      0      0      0      0      0  7.00   -0.50E-03    0
007D1.WCT    4228.0      0      0      0      0      0  7.00   -0.50E-03    0
008D1.WCT    4414.0      0      0      0      0      0  7.00   -0.50E-03    0
009D1.WCT    4596.0      0      0      0      0      0  7.00   -0.50E-03    0
010D1.WCT    4768.0      0      0      0      0      0  7.00   -0.50E-03    0
011D1.WCT    4878.0      0      0      0      0      0  7.00   -0.50E-03    0
012D1.WCT    4972.0      0      0      0      0      0  7.00   -0.50E-03    0
013D1.WCT    4480.0      0      0      0      0      0  7.00   -0.50E-03    0
014D1.WCT    5228.0      0      0      0      0      0  7.00   -0.50E-03    0

  File name  Pmax    E_Tot  T_err  S_err  O2_err     E_err  Sd_fact    E_Min  
015D1.WCT    5192.0      0      0      0      0      0  7.00   -0.50E-03    0
016D1.WCT    4410.0      0      0      0      0      0  7.00   -0.50E-03    0
017D2.WCT    5222.0      0      0      0      0      0  7.00   -0.50E-03    0
018D1.WCT    5190.0      0      0      0      0      0  5.00   -0.50E-03    
019D1.WCT    5136.0      0      0      0      0      0  5.00   -0.50E-03    
020D1.WCT    4850.0      0      0      0      0      0  5.00   -0.50E-03    
021D1.WCT    4254.0      0      0      0      0      0  5.00   -0.50E-03    
022D1.WCT    5030.0      0      0      0      0      0  5.00   -0.50E-03    
023D1.WCT    4636.0      0      0      0      0      0  5.00   -0.50E-03 
024D1.WCT    4686.0      0      0      0      0      0  5.00   -0.50E-03    
025D1.WCT    4658.0      0      0      0      0      0  5.00   -0.50E-03    
026D2.WCT    5272.0      0      0      0      0      0  5.00   -0.50E-03    
027D1.WCT    4560.0      0      0      0      0      0  5.00   -0.50E-03    
028D1.WCT    4566.0      0      0      0      0      0  5.00   -0.50E-03    
029D1.WCT    3894.0      0      0      0      0      0  5.00   -0.50E-03    
030D1.WCT    4394.0      0      0      0      0      0  5.00   -0.50E-03    
031D1.WCT    4546.0      0      0      0      0      0  5.00   -0.50E-03    
032D1.WCT    4190.0      0      0      0      0      0  5.00   -0.50E-03    
033D1.WCT    4366.0      0      0      0      0      0  5.00   -0.50E-03    
034D2.WCT    4650.0      0      0      0      0      0  5.00   -0.50E-03    
035D1.WCT    4746.0      0      0      0      0      0  5.00   -0.50E-03    
036D1.WCT    4690.0      0      0      0      0      0  5.00   -0.50E-03    
037D1.WCT    4606.0      0      0      0      0      0  5.00   -0.50E-03    
038D1.WCT    4928.0      0      0      0      0      0  5.00   -0.50E-03    
039D1.WCT    4524.0      0      0      0      0      0  5.00   -0.50E-03    
040D1.WCT    5280.0      0      0      0      0      0  5.00   -0.50E-03    
041D1.WCT    5242.0      0      0      0      0      0  5.00   -0.50E-03    
042D1.WCT    5312.0      0      0      0      0      0  5.00   -0.50E-03    
043D1.WCT    5306.0      0      0      0      0      0  5.00   -0.50E-03    
044D1.WCT    5350.0      0      0      0      0      0  5.00   -0.50E-03    
045D1.WCT    5386.0      0      0      0      0      0  5.00   -0.50E-03    
046D2.WCT    5346.0      0      0      0      0      0  5.00   -0.50E-03    
047D1.WCT    5384.0      0      0      0      0      0  5.00   -0.50E-03    
048D1.WCT    5280.0      0      0      0      0      0  5.00   -0.50E-03    
049D1.WCT    5284.0      0      0      0      0      0  5.00   -0.50E-03    
050D1.WCT    5270.0      0      0      0      0      0  5.00   -0.50E-03    
051D1.WCT    5108.0      0      0      0      0      0  5.00   -0.50E-03    
052D1.WCT    5394.0      0      0      0      0      0  5.00   -0.50E-03    
053D1.WCT    4926.0      0      0      0      0      0  5.00   -0.50E-03    
054D1.WCT    4872.0      0      0      0      0      0  5.00   -0.50E-03    
055D1.WCT    4930.0      0      0      0      0      0  5.00   -0.50E-03    
056D1.WCT    4912.0      0      0      0      0      0  5.00   -0.50E-03    
057D2.WCT    5042.0      0      0      0      0      0  5.00   -0.50E-03    
058D1.WCT    4980.0      0      0      0      0      0  5.00   -0.50E-03    
059D1.WCT    4978.0      0      0      0      0      0  5.00   -0.50E-03    
060D1.WCT    4990.0      0      0      0      0      0  5.00   -0.50E-03    
061D1.WCT    4930.0      0      0      0      0      0  5.00   -0.50E-03    
062D1.WCT    4932.0      0      0      0      0      0  5.00   -0.50E-03    
063D1.WCT    4970.0      0      0      0      0      0  5.00   -0.50E-03    
064D1.WCT    5008.0      0      0      0      0      0  5.00   -0.50E-03    
065D1.WCT    5012.0      0      0      0      0      0  5.00   -0.50E-03    
066D2.WCT    4884.0      0      0      0      0      0  5.00   -0.50E-03    
067D1.WCT    4868.0      0      0      0      0      0  5.00   -0.50E-03    
068D1.WCT    4806.0      0      0      0      0      0  5.00   -0.50E-03    
069D1.WCT    4808.0      0      0      0      0      0  5.00   -0.50E-03    
070D1.WCT    4814.0      0      0      0      0      0  5.00   -0.50E-03    
071D1.WCT    4850.0      0      0      0      0      0  5.00   -0.50E-03    

  File name  Pmax    E_Tot  T_err  S_err  O2_err     E_err  Sd_fact    E_Min  
072D1.WCT    4728.0      0      0      0      0      0  5.00   -0.50E-03    
073D1.WCT    4706.0      0      0      0      0      0  5.00   -0.50E-03    
074D1.WCT    4704.0      0      0      0      0      0  5.00   -0.50E-03    
075D1.WCT    4640.0      0      0      0      0      0  5.00   -0.50E-03    
076D2.WCT    4652.0      0      0      0      0      0  5.00   -0.50E-03    
077D1.WCT    4600.0      0      0      0      0      0  5.00   -0.50E-03    
078D1.WCT    4512.0      0      0      0      0      0  5.00   -0.50E-03    
079D1.WCT    4374.0      0      0      0      0      0  5.00   -0.50E-03    
080D1.WCT    4392.0      0      0      0      0      0  5.00   -0.50E-03    
081D1.WCT    4394.0      0      0      0      0      0  5.00   -0.50E-03 
082D1.WCT    4408.0      0      0      0      0      0  5.00   -0.50E-03 
083D1.WCT    4436.0      0      0      0      0      0  5.00   -0.50E-03 
084D1.WCT    4486.0      0      0      0      0      0  5.00   -0.50E-03 
085D1.WCT    4508.0      0      0      0      0      0  5.00   -0.50E-03 
086D1.WCT    4582.0      0      0      0      0      0  5.00   -0.50E-03 
087D1.WCT    4628.0      0      0      0      0      0  5.00   -0.50E-03 
088D1.WCT    4618.0      0      0      0      0      0  5.00   -0.50E-03 
089D1.WCT    4540.0      0      0      0      0      0  5.00   -0.50E-03 
090D1.WCT    4534.0      0      0      0      0      0  5.00   -0.50E-03 
091D1.WCT    4446.0      0      0      0      0      0  5.00   -0.50E-03 
092D1.WCT    4318.0      0      0      0      0      0  5.00   -0.50E-03 
093D1.WCT    4382.0      0      0      0      0      0  5.00   -0.50E-03 
094D1.WCT    4352.0      0      0      0      0      0  5.00   -0.50E-03 
095D1.WCT    4272.0      0      0      0      0      0  5.00   -0.50E-03 
096D1.WCT    3954.0      0      0      0      0      0  5.00   -0.50E-03 
097D1.WCT    3446.0      0      0      0      0      0  5.00   -0.50E-03 
098D2.WCT    4380.0      0      0      0      0      0  5.00   -0.50E-03 
098D4.WCT    4382.0      0      0      0      0      0  5.00   -0.50E-03 
099D1.WCT    4286.0      0      0      0      0      0  5.00   -0.50E-03 
100D1.WCT    4286.0      0      0      0      0      0  5.00   -0.50E-03 
101D1.WCT    4368.0      0      0      0      0      0  5.00   -0.50E-03 
102D1.WCT    4404.0      0      0      0      0      0  5.00   -0.50E-03 
103D1.WCT    4360.0      0      0      0      0      0  5.00   -0.50E-03 
104D1.WCT    4542.0      0      0      0      0      0  5.00   -0.50E-03 
105D1.WCT    4556.0      0      0      0      0      0  5.00   -0.50E-03 
106D1.WCT    4446.0      0      0      0      0      0  5.00   -0.50E-03 
107D1.WCT    4460.0      0      0      0      0      0  5.00   -0.50E-03 
108D1.WCT    4424.0      0      0      0      0      0  5.00   -0.50E-03 
109D1.WCT    4350.0      0      0      0      0      0  5.00   -0.50E-03 
110D1.WCT    4506.0      0      0      0      0      0  5.00   -0.50E-03 
111D1.WCT    4418.0      0      0      0      0      0  5.00   -0.50E-03 
112D1.WCT    4498.0      0      0      0      0      0  5.00   -0.50E-03 
113D1.WCT    4466.0      0      0      0      0      0  5.00   -0.50E-03 
114D1.WCT    4498.0      0      0      0      0      0  5.00   -0.50E-03 
115D1.WCT    4564.0      0      0      0      0      0  5.00   -0.50E-03 
116D1.WCT    4624.0      0      0      0      0      0  5.00   -0.50E-03 
117D1.WCT    4676.0      0      0      0      0      0  5.00   -0.50E-03 
118D1.WCT    4740.0      0      0      0      0      0  5.00   -0.50E-03 
119D1.WCT    4702.0      0      0      0      0      0  5.00   -0.50E-03 
120D1.WCT    4712.0      0      0      0      0      0  5.00   -0.50E-03 
121D1.WCT    4720.0      0      0      0      0      0  5.00   -0.50E-03 
122D1.WCT    4636.0      0      0      0      0      0  5.00   -0.50E-03 
123D1.WCT    4586.0      0      0      0      0      0  5.00   -0.50E-03 




E.2  COMMENTS ON DQ EVALUATION OF TUNES LEG I (P17C) HYDROGRAPHIC DATA
     (A. Mantyla)
     2 November 1993

Aside from suffering some lost data due to trip malfunctions common to CTD-
Rosette casts, the sampling density and data quality of this cruise are quite 
good. The TUNES Leg I data are comparable to the TPS-24 cruise, and are better 
than most of the limited nearby historical data. The TUNES silicate, phosphate, 
and perhaps salinity tend to be lower than other cruises while the oxygen and 
nitrate data agree well. I expect the most recent data set to be the most 
reliable. The TUNES Leg I cruise track at 135°W helps to fill in a data sparse 
series of Marsden Squares in the Pacific and will certainly improve the Pacific 
deep data array.

The data originators have done a very meticulous job in evaluating the data and 
in solving trip problems, but they may have been overly zealous in flagging data 
that merely looked "funny" as "bad" data. Nutrients in particular, that were 
within the hoped for 1% of full scale accuracy range, were often flagged. In 
those cases, it is entirely possible that the flagged data could be closer to 
correct, and the accepted data slightly in error. However, I understand the 
desire to have an internally consistent data set and have not changed many of 
the flags.

Double trips, delayed trips and other mis-trips were frequent in the first 1/4 
of the cruise and most trip problems have been resolved. I've noted a few other 
possible trip depth assignment errors below that if corrected, would change the 
data quality flags from "bad" or "questionable" to "good data". On some 
stations, a large number of bottles were flagged "4" (did not trip correctly) 
due to mis-trips or double-trips causing subsequent planned trips to be off by 
one or more target depths. Comparisons of the water sample salinity and oxygen 
measurements with the CTDO info is usually sufficient to match the correct CTD 
trip data to the water sample data with a reasonable degree of certainty, and 
the data originators have done that quite well for this cruise. I have not 
changed any of the "4" flags, although I believe that most should NOT be flagged 
"did not trip correctly" for the following reason: the initial mis-trip or 
double-trip represents a missed planned sampling depth and could even be a trip 
between planned depths and should be flagged as a problem. However, the 
subsequent trips are usually routine or normal, except that the initial CTD 
information assigned to the trip is incorrect. Once the correct trip info has 
been aligned with the water sample data, there really is little question as to 
the correctness of the data, and those levels should be accepted as OK rather 
than to leave doubt about the data by using the "4" bottle code.

The deep water salinity data early in the cruise bounced around a little more 
than one would expect from good salinometer operation, but settled down as the 
cruise progressed. Between stations 48 and 77, bottle 22 was strangely low in 
salinity 19 out of 29 stations, initially by about .012 and finally by about 
.022 for stations 73 to 77. Yet, the oxygen and nutrient data appeared to be 
fine. I don't know of anything that could affect the salinity in the low 
direction and not affect the other measurements. At any rate the problem went 
away once the bottle was finally replaced.

Many bottle oxygens were flagged as bad or questionable based on comparisons 
with the CTD O2, as if the CTD O2 data were perfect. I doubt that it is, and 
apparently ODF does not consider it good enough to report with the bottle data. 
They should make an effort to do so, as most other organizations are satisfying 
the WOCE reporting expectations of including the CTD oxygen data. If the UP 
water sample O2's are being evaluated against the down CTD O2 data, that may not 
be appropriate because of occasional real water mass changes between down and up 
casts and particularly in active interfingering of shallower layers that was 
common on this cruise. Some O2 data had been flagged bad even when it agreed 
with the CTD O2(!), usually when the comment "air leak" appeared on the sample 
log sheet. An air leak may well affect gas samples, but if it is at the level 
beyond the last reported significant figure, that should not be reason to flag 
the O2 data as "bad".

Some of the nutrient problems probably could be resolved by careful evaluation 
of standards and blanks or possible shifts in machine response (PO4), but the 
effort probably would not be worth the return in a few improved nutrient 
stations at this stage.

The following are some specific problems that should be looked at:

STATIONS 1 and 2: 
Bottle salts average .008 less than CTD, yet the data comments form ODF indicate 
no difference at 303db and 353db. Station 2: The dot sea file shows a difference 
of .0070 and .0058. Is there a problem with the final CTD data here? Or was it a 
poor salinometer run? Discrepancy needs to be resolved.

STATION 6: 
Initial hang-up at bottle 34 caused bottles 14 and 34 to trip one depth 
shallower than intended. All flagged "4", "Did not trip correctly". Actually, 
CTD verifies trip levels, all except possibly 34 and 30 tripped OK. Suggest 
using "4" code at 34 and 30, accept others as good.

STATION 7: 
#31 at 3034db: Salinity and $0 sub 2$, flagged questionable, appear to belong 1 
depth shallower. Nutrients would fit there also. Suggest moving the data to 
2849db and flag the data OK.

STATION 8: 
249db and 354db: water samples deleted because of mis-trips. ODF data comments 
lists original analyses for the two depths identical to the last decimal place. 
Is that true? Not likely for 2 non-adjacent mis-trips. Recheck deleted data.


STATION 11: 
3401db: Looks like data belongs 1 level up at missed unlisted depth of 3145db. 
If done, remove uncertain flag from O2.

STATION 12: 
As on station 6, bottles 13-34 tripped 1 planned level off, but CTD verifies 
correct depths. Suggest flag bottles OK, except for #20 and #29, use "4" code.

STATIONs 15: 
Bottle 31 at 3963db flagged "u", but would be OK at next planned level up at 
3706db (not listed), as would salinity and nutrients. Suggest change and flag 
bottle "4", data OK. #33 and #34, 4477db and 4730db: nearly identical nutrients 
and salinity, O2 close. Most likely both tripped at same depth. #34 has hung-up 
on previous stations, so suggest move to 4477db. If not, flag silica "u".

STATION 23: 
Bottle 34 at 4268db data flagged "u", but is same as data at 4067db. Suggest 
move bottle 34 one depth up and accept data as OK, bottle "4 flag".

STATION 34: 
Deepest 3, 4276-4650db, clearly bad, must be titration or pickling error. 
Suggest omit. Curiously, these were flagged only "questionable", while O2 at 
3297db, only slightly off, was flagged "bad".

STATION 44: 
#18 and #36, 1011db and 5348db: O2's are identical, 173.3mm, both bad. Could 
there be some data recording error? If no error found, recommend deleting O2 at 
1011db.

STATION 84: 
Bottles 12, 2-11 (0-352db) flagged "4 did not trip correctly". Ramp shift 
probably offset, but CTD verifies correct trip depths, there is no uncertainty. 
Suggest change flags to OK (2).

STATION 86: 
First 12 bottles, as on 84. Accept as OK.

STATION 98: 
Cast 2, 36 fully sampled depths; and cast 4, 11 salinity and O2 checks only, are 
merged together. They should not be merged as they are entirely separate 
profiles. List the casts separately.



E.2.1  RESPONSE TO DQ EVALUATION OF TUNES LEG 1 (P17) HYDROGRAPHIC DATA
       (Lynne D. Talley and Mizuki Tsuchiya)
       June 15, 1994

Bottle flags: The operations manual states that a flag of "4" means that the 
bottle did not trip correctly. Using perphas the incorrect impression that if 
there had been any problem with tripping that the bottle should be flagged "4" 
even if it was felt that the correct tripping depth had been identified. Since 
this assumption seems to be incorrect many of the bottle flags "4" should be 
changed to "3".

Salinity at bottle 22: In the orginal report to the WHPO a note was included 
concering the salinities from station 48, bottle 22 to station 77 are slightly 
suspicious. This does indeed seem odd, and Arnold Mantyla confirmed that the 
values are "strangely low" and that this is odd. Not all bottle 22 salts are 
flagged, but the majority are between stations 48 and 77:


                   St  /C Bot  Pres    Salt      Qual1
                   --  -- --- ------  -------  --------
                    8  1  22  1615.5  -9.0000  32555555
                   11  1  22  1717.8  34.5642  22424444
                   14  1  22  1806.6  34.5747  22422222
                   48  1  22  2199.2  34.6299  32422222
                   54  1  22  1818.8  34.6067  32422222
                   57  2  22  2019.9  34.6209  32422222
                   59  1  22  1881.2  34.6095  32422322
                   61  1  22   353.1  34.4822  32422222
                   62  1  22  1818.2  -9.0000  92999999
                   63  1  22  2025.5  34.6293  32422222
                   64  1  22  1719.2  34.6025  32422222
                   65  1  22  2020.5  34.6295  32422222
                   66  2  22  1614.6  34.5945  32422222
                   67  1  22  1717.5  34.6014  32422222
                   68  1  22  1619.4  34.6060  32422222
                   69  1  22  1816.6  34.6185  32422222
                   70  1  22  1617.6  34.6089  32422222
                   71  1  22  1820.4  34.5942  32422222
                   72  1  22  1613.1  34.6040  32422222
                   73  1  22  1619.5  34.5928  32422222
                   74  1  22  1614.7  34.5892  32422222
                   75  1  22  1623.2  34.5902  32422222
                   76  2  22  1620.0  34.5917  32422222
                   77  1  22  1410.4  34.5750  32422222
                  102  1  22  1624.6  -9.0000  92999999


STATION 1 salinity: 
Although the station is listed in the DQE comments, there is actually no 
question listed there for station 1, so no response.

STATION 2 salinity: 
yes, the DQE is correct; the offsets at 303 and 353 db are really -0.007 and -
0.006. No change to flags in sea file. The documentation should be changed to 
reflect this. Here is the corrected text for station 2, in section D (Bottle 
data comments):

STATION 002

113  Bottle was closed but not intended as a sample. NBs 14 thru 17 were open as 
intended and ramp shaft in correct position. Water samples same as NB36 so 
assume NB 13 closed at first trip. This level is not reported.
129 @ 303db  Sample Log: "Air vent open" Delta-S -0.007 at 303db, in line with 
all other offsets on this station. O2 agrees with CTDO.
130 @ 353db  Sample Log: "Air vent open" Delta-S -0.006 at 353db, in line with 
all other offsets on this station. O2 agrees with CTDO.

STATION 6: 
mostly agree with DQE except for bottle 12. i.e. 6/1/30: bottle flag 4; 6/1/34: 
bottle flag 4; 6/1/12: bottle flag should be kept at 3 since "bottom cap knocked 
open"; 6/1/13-33 except 30 and 34: bottle flag 2

STATION 7: 
agree with DQE - change as requested i.e. 7/1/30 and 7/1/31: move salt, oxygen, 
nutrients from level 31 (3033) up to level 30 (2849 db) and flag as OK.

STATION 8: 
the 249 dbar values in the doc file are in error. They should read "Delete 
salinity (34.209), oxygen (2.3700), no3 (36.4), po4 (2.70), sio3 (97.5), no2 
(0.00)." They have been changed in the new documentation.

STATION 008

110 @ 249db  Sample log: Leaker. Delta-S .17 high at 249db. Nutrients also 
appear to be from deeper water. O2 looks ok. Delete salinity, o2, sil, no3, no2, 
po4, 
34.209  2.37  97.5  36.4  0.00  2.70, respectively.

STATION 11: 
The measured salinity at bottle 31 is 34.667. The CTD salinity at 3401 is 
34.669. The CTD salinity at 3145 is 34.663. The difference between measured and 
CTD salts for other bottles near this is on the order of -0.001 and -0.003. Thus 
increasing this difference to -0.006 by shifting the values to 3145 does not 
seem justified.

STATION 12: 
agree with DQE - change as requested i.e. 
6/1/13-34: change bottle flag to 2 except for 
6/1/20, 6/1/29: keep bottle flag of 4

STATION 15 
It is true that shifting bottle 31 from 3962 db to 3706 db would not be a 
problem with respect to salinity (it would actually slightly improve the 
difference between CTD and bottle salinity). The change in potential temperature 
is slight but enough that the oxygen seems to fit a bit better at 3706 than at 
3962. The nutrients fit pretty well at either pressure and theta. There is a 
slight improvement to oxygen; the nutrients fit alright at both 3962 and 3706. 
We could therefore go either way - in our own version of the file, we will not 
change anything about bottle 31 unless the WHPO makes a decision to change the 
values.

                      ctdprs  theta   ctdsal   bottlesal
                      ------  ------  -------  ---------
                      3706    1.4824  34.6761  34.6768
                      3962    1.4810  34.6786  34.6768


Thus we could have the following entry in the sea file:

15 1 31 31 3706.0 1.4824 34.6761 1.1954 34.6768 136.9 165.48 37.34 0.00 2.58 42222222


This is based on the 2dbar CTD data, since I don't have the raw CTD data here. 
If you would like this to be more refined, I can go back to ODF>

For station 15, bottle 34: change all CTD to same as bottle 33 at 4477, as 
suggested by DQE.

STATION 23: 
agree with DQE - change as requested, i.e. change all bottle 34 CTD data to be 
the same as bottle 33, no flags.

STATION 34: 
We assume that the DQE means only the oxygen values in the statement as the 
other parameters seem OK to us. Change as requested because values are truly 
terrible (all about 0 oxygen near the bottom).

STATION 44: 
The oxygen values at 1011 db and 5348 db had already been flagged as "4" 
(44/1/18 and 44/1/36)

STATION 84: 
agree with DQE - change bottle flags 84/1/12, 2-11 to 2 as requested

STATION 86: 
agree with DQE - change bottle flags as requested 86/1/12, 1-11 as requested.

STATION 98: 
agree with DQE - change as suggested. I believe that the latest version of this 
file which you received had these two casts separated (but I could be wrong).

Additional list of QUALT2 suggestions (DQE said that he has not listed many 
changes to "4" here - they are in the discussion above, so complete list should 
include above comments):


6/1/29  agree                   53/1/35 agree
7/1/34  agree                   54/1/5  agree
8/1/26  disagree (we would      54/1/6  agree
        retain 3 for silicate)  54/1/30 agree
8/1/27  agree                   55/1/8  agree
                                55/1/16 disagree see DQE comment on 59/1/4: this
                                        is the beginning of some O2 structure. 
11/1/30 agree                           It is quite apparent in CTDO2 overlays 
13/1/30 agree                           (plot enclosed).
14/1/13 agree                   59/1/14 agree
16/1/33 agree                   63/1/12 agree
19/1/35 agree                   64/1/28 agree
20/1/10 agree                   64/1/30 agree
20/1/34 agree                   65/1/27 agree
21/1/1  agree                   65/1/28 agree
21/1/3  agree                   68/1/22 agree
26/2/36 agree                   74/1/30 agree
27/1/28 agree                   75/1/29 agree
31/1/4  agree                   76/2/25 agree
32/1/15 agree                   77/1/20 agree
34/2/27 agree                   80/1/12 agree
34/2/6  agree                   86/1/2  agree
34/2/9  agree                   87/1/70 agree
34/2/10 agree                  108/1/8  agree
34/2/11 agree                  108/1/31 agree
34/2/12 agree                  116/1/3  agree
37/1/24 agree                  118/1/17 agree
39/1/32 agree                  119/1/25 agree
40/1/36 agree                  120/1/8  agree
45/1/9  agree                  123/1/10 agree
52/1/29 agree





E.3.  CFC Data Quality Evaluation (DQE) on P17C 
      (F. A. Van Woy)
      January 13, 1995


We recently ftp'd the quality word changes that I made for Tunes leg 1, Pl7C. I 
believe that a reasonable assessment has been done. If the data originator 
wishes that I reconsider my choices, I will need to be provided with the 
following:

1)  CFC air concentrations for each station
2)  Calibration curves used for calculations
3)  Chromatograms
4)  Sample blanks applied and how determined
5)  Stripper efficiency results
6)  Contour plots

It is recommended on future cruises that the observer draw and run more 
replicate samples along with running more deep "blank" samples to assess the 
sample blank more thuroughly.

I believe that a reasonable quality assessment of the data has been done without 
the above items and any additional effort would take a fairly intensive 
involvement from this laboratory.


4 JAN 95
         NBR CASTNO SAMPNO CTDPRS  CFC-11  CFC-12  QUALT1 QUALT2
         --- ------ ------ ------  ------  ------  ------ ------
           4   1      22    800.2   0.037            2~     3~
           6   1      20    808.3           0.013    ~2     ~3
           6   1      21    909.1   0.019   0.009    22     33
           6   1      22   1009.3   0.021   0.013    22     33
           6   1      34   3451.0           0.011    ~2     ~3
           6   1      35   3867.1           0.020    ~2     ~3
           6   1      36   4073.0   0.008   0.033    66     23
           7   1      19   1006.3   0.018   0.003    28     32
          10   1      13    407.4   0.649            2~     3~
          11   1      20   1108.9   0.014   0.009    28     33
          12   1      13    607.9   0.179            2~     3~
          12   1      32   4322.5   0.013   0.006    27     32
          13   1      20    908.6   0.025            2~     3~
          14   1       1      3.0   2.805            2~     3~
          14   1       3     48.7   2.922            2~     3~
          14   1       5    101.5   3.105            2~     3~
          14   1      33   4578.0   0.014   0.000    47     32
          20   1      24   2023.7   0.019            2~     3~
          22   1      14    602.7   0.161            8~     3~
          22   1      16    809.9   0.019            2~     3~
          22   1      18   1007.7   0.017            8~     3~
          22   1      36   5028.9   0.010            2~     3~
          27   1      33   3803.4           0.012    ~2     ~3
          29   1       1      1.6   2.573   1.315    28     33

         NBR CASTNO SAMPNO CTDPRS  CFC-11  CFC-12  QUALT1 QUALT2
         --- ------ ------ ------  ------  ------  ------ ------
          29   1       2     81.4   2.453   1.344    28     33
          29   1       3    127.2   2.590   1.320    22     33
          29   1       4    151.9   2.515   1.320    28     33
          29   1       5    176.7   2.617   1.377    22     33
          29   1       6    203.2   2.521   1.289    28     33
          29   1      35   3658.5           0.010    ~2     ~3
          29   1      36   3894.2           0.009    ~2     ~3
          31   1       1      1.2   2.292            2~     3~
          31   1       2     79.5   2.323            2~     3~
          31   1       3    110.5   2.283            2~     3~
          31   1      36   4545.9           0.011    ~2     ~3
          33   1      35   4128.0           0.012    ~2     ~3
          33   1      36   4366.3           0.013    ~2     ~3
          34   2       9   4065.5           0.011    ~2     ~3
          34   2      10   4275.6           0.013    ~2     ~3
          34   2      11   4483.0           0.013    ~2     ~3
          36   1      34   4268.1           0.011    ~2     ~3
          36   1      35   4487.7           0.010    ~2     ~3
          36   1      36   4689.1           0.009    ~2     ~3
          39   1       8    227.5           1.336    ~8     ~3
          43   1      28   3195.6   0.015            2~     3~
          44   1      13    503.6           0.020    ~2     ~3
          44   1      17    913.6   0.012   0.007    22     33
          57   2      11    401.8   0.009   0.015    22     33
          59   1       1      0.2   1.707   1.003    28     33
          61   1      35   2225.1   0.013            2~     3~
          63   1      10    263.4           0.058    ~2     ~3
          63   1      11    355.0           0.028    ~6     ~3
          66   2       7    127.8           0.139    ~2     ~3
          66   2       8    152.7           0.104    ~2     ~3
          66   2       9    202.5           0.082    ~2     ~3
          66   2      10    253.7           0.051    ~2     ~3
          66   2      11    304.3           0.050    ~2     ~3
          67   1      10    182.1           0.073    ~2     ~3
          67   1      11    243.3           0.067    ~2     ~3
          67   1      12    306.0           0.054    ~2     ~3
          71   1      11    313.6           0.054    ~2     ~3
          76   2      11    307.9           0.088    ~2     ~3
          77   1       3     90.2   1.618    .937    22     33
          84   1       3     91.9   1.457   0.863    22     33
          86   1      11    384.8   0.088   0.060    22     33
          90   1      17    605.1           0.014    ~2     ~3
          94   1      11    304.6           0.148    ~2     ~3
          94   1      19   1008.8  -0.001   0.014    72     23
          96   1      14    306.1           0.256    ~2     ~3
          96   1      15    350.5           0.134    ~2     ~3
          96   1      16    396.1           0.114    ~2     ~3
          96   1      17    509.5           0.059    ~2     ~3
          96   1      18    599.6           0.088    ~2     ~3
          98   2      21   1617.9           0.010    ~2     ~3
         100   1      16    606.1           0.012    ~2     ~3
         100   1      17    708.8           0.007    ~2     ~3
         100   1      18    806.4           0.010    ~2     ~3
         100   1      20   1011.6           0.011    ~2     ~3
         100   1      21   1215.7           0.013    ~2     ~3
         108   1      16    711.5           0.011    ~2     ~3

         NBR CASTNO SAMPNO CTDPRS  CFC-11  CFC-12  QUALT1 QUALT2
         --- ------ ------ ------  ------  ------  ------ ------
         112   1      18    809.3           0.016    ~2     ~3
         122   1       1      0.2           0.950    ~2     ~3
         122   1      18    960.0           0.008    ~2     ~3
         123   1      36   4581.5   -0.001  0.009    72     23




E.4.  Final CFC Data Quality Evaluation (DQE) Comments on P17C
      (David Wisegarver)
      Dec 2000

During the initial DQE review of the CFC data, a small number of samples were 
given QUALT2 flags which differed from the initial QUALT1 flags assigned by the 
PI. After discussion, the PI concurred with the DQE assigned flags and updated 
the QUAL1 flags for these samples.

The CFC concentrations have been adjusted to the SIO98 calibration Scale (Prinn 
et al. 2000) so that all of the Pacific WOCE CFC data will be on a common 
calibration scale.

For further information, comments or questions, please, contact the CFC PI for 
this section 
                      Rana Fine (rfine@rsmas.miami.edu)
                                      or
                    David Wisegarver (wise@pmel.noaa.gov)

Additional information on WOCE CFC synthesis may be available at: 

                        http://www.pmel.noaa.gov/cfc.

Prinn, R. G., R. F. Weiss, P. J. Fraser, P. G. Simmonds, D. M. Cunnold, 
    F. N. Alyea, S. O'Doherty, P. Salameh, B. R. Miller, J. Huang, 
    R. H. J. Wang, D. E. Hartley, C. Harth, L. P. Steele, G. Sturrock, 
    P. M. Midgley, and A. McCulloch, A history of chemically and radiatively
    important gases in air deduced from ALE/GAGE/AGAGE. Journal of Geophysical
    Research, 105, 17,751-17,792, 2000.



E.5.  P17C TUNES-1  Final Report for Large Volume Samples
      (Robert M. Key)
      July 1, 1996

1.0   GENERAL INFORMATION

WOCE section P17C was the first in a series of three cruise legs collectively 
referred to as "TUNES". Mizuki Tsuchiya of SIO was chief scientist for this 
leg. This report covers details of data collection and analysis for the large 
volume Gerard samples. The reader is referred to "Documentation for WOCE 
Hydrographic Program section P17C" by L.D. Talley and M. Tsuchiya as the 
primary source for cruise information. Significant portions of this report 
(hydrography) were taken directly from a data report prepared by the 
Oceanographic Data Facility at Scripps Institution of Oceanography (dated 
July 17, 1995). Detailed text describing specific sample/bottle problems 
which were in the ODF report are reproduced here as an appendix.

Nine large volume (LV) stations were occupied on this leg. The cruise plan 
called for 2 Gerard casts of 9 barrels each at each LV station. The planned 
sampling density was 1 station every 5° of latitude (~300nmi). Each station, 
except for station 34, included at least one deep cast (2500db to the 
bottom), and an intermediate (1000db to 2500db) cast. In the event of 
mistripped Gerard sampler(s), casts were repeated as time allowed in an 
attempt to collect the full suite of samples. The purpose of these casts was 
to collect samples for 14C analysis. 14C coverage for the upper water column 
was done via small volume AMS sampling from the Rosette. This report covers 
only the large volume Gerard sampling.

All LV casts for the TUNES cruises were done using the stern A-frame on the R/V 
Thomas Washington. As is generally the case, the combination of a small vessel 
with working off the stern led to an elevated failure rate for the LV work 
relative to working off the side of a larger vessel. This problem is a result 
of accelerations on the trawl wire caused by ship motion and sea state. Slowing 
the lowering rate to 50 meters per minute or less reduced the failure rate. The 
Gerard barrel platform, as set up in port prior to the cruise, did not allow 
enough clearance for barrel deployment and recovery. The Chief Engineer cut the 
platform loose and rewelded it to the deck about one foot forward. The spring-
loaded trapping-pin was no longer usable so a chain was shackled to one forward 
corner of the platform, passed aft of the wire then hooked to the other forward 
corner to hold the trawl wire in the platform "V" while the barrels were being 
attached and detached. Limited fantail space and the low trawl wire lead 
required that the crane work over the wire to move barrels from racks to near 
the center-line just forward of the platform, then the barrel was unhooked and 
the crane moved to the other side of the wire and re-hooked to move the barrel 
to the attachment position. This procedure was reversed for recovery. Problems 
were minimized by the exceptional effort and capability of the Washington's 
crew. Table 1 summarizes the LV sampling.

Table 1. LV Sampling Summary

              Station  Cast  Latitude   Longitude   No. Ger.
                                                    Samples
              -------  ----  ---------  ----------  -------
                17      1    34°35.7'N  134°59.1'W     9
                        3    34°36.4'N  134°56.6'W     5
                        4    34°37.0'N  134°55.7'W     1
                        5    34°37.1'N  134°55.2'W     3
                26      1    30°0.8'N   134°58.1'W     9
                        3    30°2.2'N   134°53.6'W     9
                34      1    26°1.2'N   134°59.5'W     9
                46      1    19°58.5'N  135°0.3'W      8
                        3    19°58.8'N  135°1.9'W      9
                57      1    14°28.6'N  134°59.3'W     9
                        3    14°26.5'N  134°58.4'W     9
                66      1     9°58.8'N  135°2.1'W      9
                        3     9°56.5'N  135°5.5'W      4
                        4     9°55.8'W  135°5.9'W      5
                76      1     5°0.2'N   134°58.9'W     9
                        3     4°57.7'N  134°56.0'W     9
                98      1     0°0.3'S   135°9.5'W      9
                        3     0°0.3'S   135°8.2'W      9
               121      2     5°4.6'S   135°0.8'W      5
                        3     5°6.1'S   135°1.5'W      4
                        4     5°7.9'S   135°2.9'W      9
               Total   21                            152

Each Gerard barrel was equipped with a piggyback 5 liter Niskin bottle which 
had a full set of high precision reversing thermometers to determine sampling 
pressure and temperature. Both Gerard and Niskin were sampled for salinity. 
Additionally, each Gerard was sampled for silicate and radiocarbon. The 
salinity samples from the piggyback bottle were used for comparison with the 
Gerard barrel salinities to verify the integrity of the Gerard sample. 
Discrete sample information was recorded on a log sheet. Normal sampling 
practice is to open the Gerard drain valve before opening the air vent to see 
if water escapes, indicating the presence of a small air leak in the sampler. 
This observation ("air leak"), and other comments ("lanyard caught in lid", 
"valve left open", etc.) which may indicate some doubt about the integrity of 
the water samples were also noted on the log sheets. These comments are 
included in the appendix. The hydrographic data were entered into the 
shipboard data system and processed as analyses were completed. The bottle 
data were brought to a usable, though not final, state at sea. ODF data 
checking procedures included verification that the sample was assigned to the 
correct depth. ODF compared salinity and nutrient data with data from 
adjacent stations and with the rosette cast data from the same station. Any 
comments regarding the water samples were investigated. The raw data computer 
files were also checked for entry errors.

2.0  PERSONNEL

LV sampling for this cruise was under the direction of the principal 
investigator, Robert M. Key (Princeton). All LV 14C extractions at sea were 
done by Leonard Lopez (SIO-ODF). In addition to Key and Lopez, deck work was 
done by the SIO CTD group with assistance from many of the scientific party. 
Lopez was primarily responsible for reading thermometers. Salinities and 
nutrients were analyzed by the SIO CTD group and the Oregon State Univ. group 
respectively. 14C analyses were performed at Göte Östlund's laboratory (U. 
Miami, R.S.M.A.S.). Key collected the data from the originators, merged the 
files, assigned quality control flags to the 14C, rechecked the flags assigned 
by ODF and submitted the data files to the WOCE office (8/95).

3.0  RESULTS

This data set and any changes or additions supersedes any prior release. In 
this data set Gerard samples can be differentiated from Niskin samples by the 
bottle number. Niskin bottle numbers are in the range 41-50 while Gerards are 
in the range 81-94.

3.1  PRESSURE AND TEMPERATURE

Pressure and temperature for LV casts are determined by reversing 
thermometers mounted on the piggyback Niskin bottle. Each bottle was equipped 
with the standard set of 2 protected and 1 unprotected thermometer. Each 
temperature value reported on the LV casts was calculated from the average of 
four readings, provided both protected thermometers functioned normally. 
Reported temperatures are relative to the International Temperature Scale of 
1990. All thermometers, calibrations and calculations were provided by SIO-
ODF. Reported temperatures for samples in the thermocline are believed to be 
accurate to 0.01°C and for deep samples 0.005°C. Pressures were calculated 
using standard techniques combining wire out with unprotected thermometer 
data. In cases where the thermometers failed, pressures were estimated by 
thermometer data from adjacent bottles combined with wire out data. Because 
of the inherent error in pressure calculations and the finite flushing time 
required for the Gerard barrels, the assigned pressures have an uncertainty 
of approximately 10 dB. The pressures recorded in the data set for each 
Gerard-Niskin pair generally differ by approximately 0.5 dB with the Gerard 
pressure being the greater. This is because the Niskin is hung near the upper 
end of the Gerard.

3.2  SALINITY

A salinity samples was collected from each Gerard barrel and each piggyback 
Niskin bottle. Analyses were performed by the same personnel who ran the salt 
samples collected from the Rosette bottles so the analytical precision should 
be the same for LV salts and Rosette salt samples. When both Gerard and 
Niskin trip properly, the difference between the two salt measurements should 
be within the range 0.000 - 0.003 on the PSU scale. Somewhat larger 
differences can occur if the sea state is very calm and the cast is not 
"yoyo'ed" once the terminal wire out is reached. This difference is due to 
the flushing time required for the Gerard barrels and the degree of 
difference is a function of the salinity gradient where the sample was 
collected. In addition to providing primary hydrographic data for the LV 
casts, measured salinity values help confirm that the barrels closed at the 
desired depth. For the area covered by this leg, deep nutrient values 
(especially silicate) are as useful for trip confirmation as salt 
measurements due to the very low vertical gradient in salinity.

Salinity samples were drawn into 200 ml Kimax high alumina borosilicate 
bottles after 3 rinses, and were sealed with plastic insert thimbles and 
Nalgene screw caps. This assembly provides very low container dissolution and 
sample evaporation. As loose inserts were found, they were replaced to ensure 
a continued airtight seal. Salinity was determined after a box of samples had 
equilibrated to laboratory temperature, usually within 8-12 hours of 
collection. The draw time and equilibration time, as well as per-sample 
analysis time and temperature were logged.

A single Guildline Autosal Model 8400A salinometer located in a temperature 
controlled laboratory was used to measure salinities. The salinometer was 
standardized for each cast with IAPSO Standard Seawater (SSW) Batch P-114, 
using at least one fresh vial per cast. The estimated accuracy of bottle 
salinities run at sea is usually better than 0.002 PSU relative to the 
particular Standard Seawater batch used. PSS-78 salinity (UNESCO 1981) was 
then calculated for each sample from the measured conductivity ratios, and 
the results merged with the cruise database. There were some problems with 
lab temperature control throughout cruise; the Autosal bath temperature was 
adjusted accordingly. Salinities were generally considered good for the 
expedition despite the lab temperature problem.

3.3  NUTRIENTS

Nutrient samples were collected from Gerard samples. On this leg silicate 
values were measured on all samples and phosphate on a few selected samples. 
LV nutrients were measured along with Rosette nutrients so the analytical 
precision for Gerard samples should be the same as Rosette samples. For some 
unknown reason, nutrients collected from LV casts are frequently subject to 
systematic offsets from samples taken from Rosette bottles. For this reason 
it is recommended that these data be viewed primarily as a means of checking 
sample integrity (i.e. trip confirmation). The Rosette-Gerard discrepancy is 
frequently less for silicate than for other nutrients.

Nutrient samples were drawn into 45 ml high density polypropylene, narrow 
mouth, screw-capped centrifuge tubes which were rinsed three times before 
filling. Standardizations were performed with solutions prepared aboard ship 
from preweighed chemicals; these solutions were used as working standards 
before and after each cast to correct for instrumental drift during analysis. 
Sets of 4-6 different concentrations of shipboard standards were analyzed 
periodically to determine the linearity of colorimeter response and the 
resulting correction factors.

Nutrient analyses were performed on a modified 4 channel Technicon 
AutoAnalyzer II, generally within one hour of the cast. Occasionally samples 
were refrigerated at 2 to 6°C for a maximum of 4 hours. The methods used are 
described by Gordon et al. (1992), Atlas et al. (1971), and Hager et al. 
(1972). All peaks were logged manually, and all the runs were re-read to 
check for possible reading errors.

Silicate was analyzed using the technique of Armstrong et al. (1967). ODF's 
methodology is known to be non-linear at high silicate concentrations (>120 
µM); a correction for this non-linearity was applied. Phosphate was analyzed 
using a modification of the Bernhardt and Wilhelms (1967) technique.

Na2SiF6, the silicate primary standard, was obtained from Fluka Chemical 
Company and Fischer Scientific and is reported by the suppliers to be >98% 
pure. Primary standards for phosphate, KH2PO4, were obtained from Johnson 
Matthey Chemical Co. and the supplier reports purity of 99.999%.

Nutrients, reported in micromoles per kilogram, were converted from 
micromoles per liter by dividing by sample density calculated at zero 
pressure, in-situ salinity, and an assumed laboratory temperature of 25°C.

152 nutrient (silicate) analyses were performed. No major problems were 
encountered with the measurements.

3.4  14C

Most of the _14C values reported here have been distributed in a data report 
produced by Östlund (1992). That report included preliminary hydrographic 
data and is superceded by this submission.

All Gerard samples deemed to be "OK" on initial inspection at sea were 
extracted for 14C analysis using the technique described by Key (1991). The 
extracted 14CO2 /NaOH samples were returned to the Ocean Tracer Lab at 
Princeton and subsequently shipped to Östlund's lab in Miami. Both 13C and 14C 
measurements are performed on the same CO2 gas extracted from the large volume 
samples (13C analyses at M. Stuiver's lab, U. Washington). The standard for 
the 14C measurements is the NBS oxalic acid standard for radio-carbon dating. 
R-value is the ratio between the measured specific activity of the sample CO2 
to that of CO2 prepared from the standard, the latter number corrected to a 
_13C value of -19 and age corrected from today to AD1950 all according to the 
international agreement. _14C is the deviation in  from unity, of the 
activity ratio, isotope corrected to a sample _13C value of -25. For further 
information of these calculations and procedures see Broecker and Olson 
(1981), Stuiver and Robinson (1974) and Stuiver (1980). Östlund's lab reports 
a precision of 4 for each measurement based on a long term average of 
counting statistics.

Of the 152 Gerard samples collected, 14C has been measured on 148 (97%). This 
exceeds the rate funded for this work (80%).

Existing 14C data for the area sampled on this cruise is limited to a few 
GEOSECS measurements. Comparison of these two data sets indicates that they 
are in agreement to the precision of the measurements.

4.0  DATA SUMMARY

Figures 1-3 summarize the large volume 14C data collected on this leg. All _14C 
measurements with a quality flag value of 2 are included in each figure. 
Figure 1 shows the _14C values plotted as a function of pressure for the 
thermocline region (1a) and for the deep and bottom waters (1b). One sigma 
error bars (±4) are shown in both 1a. and 1b. The most noticeable 
characteristic is the strong minimum in the 2000-2600dB range for all 
stations. Figure 2 show the _14C values plotted against measured Gerard barrel 
silicate values. The rather strong 14C-silicate correlation noted for the 
TUNES-3 (P16C) data is not so evident in Figure 2. Figure 3 is a coarse 
resolution machine contoured section of the 14C distribution in the deep and 
bottom waters for this leg. The minimum decreases in intensity and scope to 
the south and has an extreme value of -251. The "bi-lobed" nature of the -
240 contour is an artifact of the gridding routine.


5.0  REFERENCES AND SUPPORTING DOCUMENTATION

Armstrong, F.A.J., C.R. Stearns, and J.D.H. Strickland, 1967. The measurement 
    of upwelling and subsequent biological processes by means of the Technicon 
    Autoanalyzer and associated equipment, Deep-Sea Research, 14, 381-389.

Atlas, E.L., S.W. Hager, L.I. Gordon and P.K. Park, 1971. A Practical Manual 
    for Use of the Technicon AutoAnalyzer in Seawater Nutrient Analyses; 
    Revised. Technical Report 215, Reference 71-22. Oregon State University, 
    Department of Oceanography. 49 pp.

Bernhardt, H. and A. Wilhelms, 1967. The continuous determination of low 
    level iron, soluble phosphate and total phosphate with the AutoAnalyzer, 
    Technicon Symposia, Volume I, 385-389.

Brewer, P.G. and G.T.F. Wong, 1974, The determination and distribution of 
    iodate in South Atlantic waters, Journal of Marine Research, 32, 1:25-36.

Broecker, W.S., and E.A. Olson, 1961, Lamont radiocarbon measurements VIII, 
    Radiocarbon, 3, 176-274.

Bryden, H.L., 1973, New polynomials for thermal expansion, adiabatic 
    temperature gradient, Deep-Sea Research, 20, 401-408.

Carpenter, J.H., 1965, The Chesapeake Bay Institute technique for the Winkler 
    dissolved oxygen method, Limnology and Oceanography, 10, 141-143.

Carter, D.J.T., 1980, (Third Edition), Echo-Sounding Correction Tables, 
    Hydrographic Department, Ministry of Defence, Taunton Somerset.

Chen, C.-T. and F.J. Millero, 1977, Speed of sound in seawater at high 
    pressures, Journal Acoustical Society of America, 62(5), 1129-1135.

Culberson, C.H., Williams, R.T., et al, August, 1991, A comparison of methods 
    for the determination of dissolved oxygen in seawater, WHP Office Report 
    WHPO 91-2.

Fofonoff, N.P., 1977, Computation of potential temperature of seawater for an 
    arbitrary reference pressure, Deep-Sea Research, 24, 489-491.

Fofonoff, N.P. and R.C. Millard, 1983, Algorithms for computation of 
    fundamental properties of seawater, UNESCO Report No. 44, 15-24.

Gordon, L.I., Jennings, Joe C. Jr., Ross, Andrew A., Krest, James M., 1992, A 
    suggested protocol for continuous flow automated analysis of seawater 
    nutrients in the WOCE Hydrographic Program and the Joint Global Ocean 
    Fluxes Study, OSU College of Oceanography Descr. Chem. Oc. Grp. Tech. Rpt. 
    92-1.

Hager, S.W., E.L. Atlas, L.D. Gordon, A.W. Mantyla, and P.K. Park, 1972, A 
    comparison at sea of manual and autoanalyzer analyses of phosphate, 
    nitrate, and silicate, Limnology and Oceanography, 17, 931-937.

Key, R.M., 1991, Radiocarbon, in: WOCE Hydrographic Operations and Methods 
    Manual, WOCE Hydrographic Program Office Technical Report.

Key, R.M., D. Muus and J. Wells, 1991, Zen and the art of Gerard barrel 
    maintenance, WOCE Hydrographic Program Office Technical Report.

Lewis, E.L., 1980, The practical salinity scale 1978 and its antecedents, 
    IEEE Journal of Oceanographic Engineering, OE-5, 3-8.

Mantyla, A.W., 1982-1983. Private correspondence.

Millero, F.J., C.-T. Chen, A. Bradshaw and K. Schleicher, 1980, A new high 
    pressure equation of state for seawater, Deep-Sea Research, 27A, 255-264.

Saunders, P.M., 1981, Practical conversion of pressure to depth, Journal of 
    Physical Oceanography, 11, 573-574.

Stuiver, M., and S.W. Robinson, 1974, University of Washington GEOSECS North 
    Atlantic carbon-14 results, Earth Planet. Sci. Lett., 23, 87-90.

Stuiver, M., 1980, Workshop on 14C data reporting, Radiocarbon, 3, 964-966.

Sverdrup, H.U., M.W. Johnson, and R.H. Fleming, 1942, The Oceans, Their 
    Physics, Chemistry and General Biology, Prentice-Hall, Inc., Englewood 
    Cliffs, N.J.

UNESCO, 1981, Background papers and supporting data on the Practical Salinity 
    Scale, 1978, UNESCO Technical Papers in Marine Science, No. 37, 144 p.



6.0	QUALITY CONTROL FLAG ASSIGNMENT

Quality flag values were assigned to all bottles and all measurements using 
the code defined in Tables 0.1 and 0.2 of WHP Office Report WHPO 91-1 Rev. 2 
sections 4.5.1 and 4.5.2 respectively. In this report the only bottle flag 
values used were 2, 3, 4 and 9. For the measurement flags values of 2, 3, 4 
or 9 were assigned. The interpretation of measurement flag 9 is unambiguous, 
however the choice between values 2, 3 or 4 is involves some interpretation. 
For this data set, the salt and nutrient values were checked by plotting them 
over the same parameters taken from the rosette at the same station. Points 
which were clearly outliers were flagged "4". Points which were somewhat 
outside the envelop of the other points were flagged "3". In cases where the 
entire cast seemed to be shifted to higher or lower concentrations (in 
nutrient values), but the values formed a smooth profile, the data was 
flagged as "2". The few phosphate measurements which were made on these 
samples are all flagged "4". Comments are given in the next section for flag 
values of 3 or 4 in almost all cases. Once the nutrient and salt data had 
been flagged, these results were considered in flagging the 14C data. There is 
very little overlap between this data set and any existing 14C data, so that 
type of comparison was impractical. In general the lack of other data for 
comparison led to a more lenient grading on the 14C data.

When using this data set for scientific application, any 14C datum which is 
flagged with a "3" should be carefully considered. My subjective opinion is 
that any datum flagged "4" should be disregarded. When flagging 14C data, the 
measurement error was taken into consideration. That is, approximately one-
third of the 14C measurements are expected to deviate from the true value by 
more than the measurement precision of ~4.

No measured values have been removed from this data set. When using this data 
set, it is advised that the nutrient data only be considered as a tool for 
judging the quality of the 14C data regardless of the quality code value. A 
summary of all flags is provided in Table 2.

Table 2. TUNES-1 Quality Code Summary

                    Reported |      WHP Quality Codes
                     Levels  | 1   2   3   4  5  6  7  8   9
              -------------- | -------------------------------
              BTLNBR  306    | 0  286  3  12  0  0  0  0    5 
              SALNTY  301    | 0  287  3  10  0  0  0  0    5 
              SILCAT  152    | 0  149  1   2  0  0  0  0  154 
              NITRAT    0    | 0    0  0   0  0  0  0  0  306 
              NITRIT    0    | 0    0  0   0  0  0  0  0  306 
              PHSPHT    9    | 0    0  0   9  0  0  0  0  297 
              REVPRS  306    | 0  306  0   0  0  0  0  0    0 
              REVTMP  296    | 0  292  0   4  0  0  0  0   10 
              DELC14  148    | 0  139  8   1  0  0  0  0  158a
              ------------------------------------------------
              a  14C large volume samples can not be collected 
                 from piggyback Niskin bottles



7.0  APPENDIX: Detailed Sample Notes

The following table lists comments recorded on the sample collection and 
thermometer sheets, and includes notes on sample flags provided by ODF. Any 
text in this listing shown in italics was added by the author in the final QC 
check which included the 14C data. The first column is the cast number 
(CASTNO) times 100 plus the bottle number (BTLNBR). In the comment field, 
"GB" or "G" stands for Gerard, "PB" refers to the piggyback 5 liter Niskin 
bottle and "N-G" is the arithmetic difference between the measured salinity 
values for a Niskin - Gerard pair.


FIGURE LEGENDS:

Figure 1a:  CTD #1 Pre-cruise Cold Pressure Calibration
Figure 1b:  CTD #1 Pre-cruise Warm Pressure Calibration

Figure 1c:  CTD #1 Post-cruise Pressure Calibration
Figure 1d:  CTD #1 Averaged Pre-/Post-cruise Pressure Calibration

Figure 2a:  CTD #2 Pre-cruise Pressure Calibration
Figure 2b:  CTD #2 Post-cruise Pressure Calibration

Figure 3:   CTD #10 Pre-cruise Pressure Calibration

Figure 4a:  CTD #1 Pre-cruise PRT-1 Temperature Calibration
Figure 4b:  CTD #1 Post-cruise PRT-1 Temperature Calibration

Figure 4c:  CTD #1 Averaged Pre-/Post-cruise PRT-1 Temperature Calibration

Figure 5a:  CTD #2 Pre-cruise PRT-1 Temperature Calibration
Figure 5b:  CTD #2 Post-cruise PRT-1 Temperature Calibration

Figure 5c:  CTD #2 Pre-cruise PRT-2 Temperature Calibration
Figure 5d:  CTD #2 Post-cruise PRT-2 Temperature Calibration

Figure 6a:  CTD #10 Pre-cruise PRT-1 Temperature Calibration
Figure 6b:  CTD #10 Pre-cruise PRT-2 Temperature Calibration

Figure 7a:  TUNES-1 Conductivity Slopes, All CTDs
Figure 7b:  TUNES-2 Conductivity Slopes, All CTDs

Figure 8a:  TUNES-1 Conductivity Offsets, All CTDs
Figure 8b:  TUNES-2 Conductivity Offsets, All CTDs

Figure 9a:  TUNES-1 Residual Conductivity Bottle-CTD Differences - All Pressures
Figure 9b:  TUNES-2 Residual Conductivity Bottle-CTD Differences - All Pressures

Figure 10a:  TUNES-1 Residual Conductivity Bottle-CTD Differences - Prs>1500dbar
Figure 10b:  TUNES-2 Residual Conductivity Bottle-CTD Differences - Prs>1500dbar

      NOTE:  Some differences fall outside of the plotted limits.
             Please refer to the bottle data quality codes.


Table 3.

Sample ID      Comment
------------   ----------------------------------------------------------
STATION 017

548 @ 497db    Sample log: "Didn't close" Lanyard stuck.  No water sample
               or therm readings. GB93 at this level (497db) has good
               salinity and SIL compared to other samples this station.

593 @ 497db    Gerard is acceptable, no temperature. See PB (48) comment.

388 @1992db    Sample log: "tripped but messenger hung" Relowered bottom 4
               barrels as cast 4.  PB (45).

446 @2249db    Sample log: "Air leak" N-G -.001 at 2248db.  Gerard (89) is
               okay.

489 @2249db    Sample log: "Air vent not tight. messenger hung - tripping
               wire loose" N-G -.001 at 2249db. Gerard SIL also ok.  Gerard
               is okay, PB (46).  Bottom 3 barrels tripped as cast 5 with
               Terminal Reading 762m (wire out when GB89 taken off wire).

141 @3155db    Delta-S(PB-G) at 3155db is 0.007, salinity is 34.665.
               Footnote salinity bad.  Gerard (83) is okay.

183 @3156db    Gerard is okay, PB (41).

142 @3660db    N-G .021 at 3660db. See 185. PB salinity calc ok. No other
               samples from Niskin.  Footnote salinity bad. Gerard (85) is
               acceptable.

185 @3660db    Sample log: "drain valve loose" N-G -.021 at 3660db.  Gerard
               salinity, silicate & phosphate match profile from other
               samples this station. PB (142) appears low. Gerard is
               acceptable, PB (42) may have leaked.

146 @4419db    Delta-S(PB-G) at 4419db is 0.002, salinity is 34.677.
               Gerard (89) is acceptable.

189 @4419db    Sample log: "air vent loose" N-G .002 at 4419db. PO4 & SIL
               from Gerard also look good.  Gerard is acceptable, PB (46).

148 @4931db    Sample log: "bottom end cap hung up" No water samples.

193 @4931db    No check sample from PB. See 148.  Gerard salinity,
               phosphate & silicate match profile from other samples this
               station.

STATION 026

345 @ 175db    Sample log: "Didn't close."  No temperature. Gerard (88) is
               acceptable.

388 @ 176db    No temperature, PB (45) did not trip.  Gerard probably okay,
               salinity agrees with rosette data.  Silicate is ~2.0 high
               vs. rosette data.

343 @ 542db    Delta-S(PB-G) at 542db is 0.004, salinity is 34.030.  Gerard
               (85) is probably okay. PB salinity is high compared with
               rosette data.

385 @ 543db    Gerard is probably okay, PB (43).  Silicate agrees with
               rosette data.

344 @ 794db    Delta-S(PB-G) at 794db is 0.005, salinity is 34.282.  Gerard
               (87) is probably okay. PB salinity is high compared with
               rosette data.

387 @ 795db    Gerard is okay, PB (44).  Silicate agrees with rosette data.

342 @1091db    Sample log: "Broken bottom block."  Gerard (84) is
               acceptable.  Delta-S(PB-G) at 1091db is 0.002, salinity is
               34.449.

142 @2997db    Delta-S(PB-G) at 2997db is -0.007, salinity is 34.657.
               Footnote salinity bad, could be drawing error.  Gerard (84)
               is acceptable.

146 @3999db    Delta-S(PB-G) at 3999db is -0.003, salinity is 34.679.
               Gerard (89) is okay. PB salinity is low compared with
               rosette data.

148 @4506db    Sample log: "Spigot was pushed in, little water in niskin"
               N-G -.003 at 4509db.  Gerard (93) is acceptable.  Delta-
               S(PB-G) at 4506db is -0.003, salinity is 34.681.

193 @4506db    Gerard is acceptable, PB (48).

149 @4761db    Delta-S(PB-G) at 4761db is 0.006, salinity is 34.683.  PI to
               decide integrity of Gerard (94).

194 @4761db    Salinity is low compared to rosette cast, too.  Silicate is
               low compared with adjoining rosette stations, but is
               acceptable. PB (49).  Footnote salinity bad.  PI to decide
               integrity of Gerard.

STATION 034

Cast 1         All samples accounted for.  C-14 extraction only.

183 @2582db    Sample log: "Needs pillow block."  PB (42).

150 @3793db    Sample log: "Replaced Niskin 46 with 50 - broken upper
               block."  Delta-S(PB-G) at 3793db is 0.009, salinity is
               34.680.  Gerard (89).

148 @4405db    Delta-S(PB-G) at 4405db is 0.004, salinity is 34.683.
               Gerard (93).

193 @4406db    Sample log: "Tightened niskin trip."  PB (48).

STATION 046

183 @3453db    Sample log: "Didn't latch - O-ring off center."  Salinity
               agrees with rosette and PB salinity, silicate agrees with
               rosette data. Let PI decide on integrity of  Gerard.  PB
               (42).

143 @3703db    Temperature is ~0.09 high, salinity agrees with Gerard and
               rosette data. Footnote temperature bad.  Gerard (84) is
               acceptable.

184 @3703db    Gerard is acceptable. See PB (43) temperature comment.
               Footnote temperature bad.

145 @4209db    No sample or temperature, Gerard (87) also had no sample.

187 @4209db    Sample log: "Didn't trip - no tripping pin."  No sample or
               temperature, PB (45) also had no sample.

189 @4465db    Sample log: "Closed but didn't latch."  Salinity agrees with
               rosette and PB salinity, silicate agrees with rosette data.
               Let PI decide on integrity of Gerard.  PB (50).

STATION 057

342 @1240db    Sample log: "Spigot pushed in."  Gerard (83) is acceptable.

383 @1241db    Sample log: "Replaced lid o-ring but still a very tight fit.
               Did not latch - swap with 88 next time."  Gerard is
               acceptable, PB (42).

350 @1511db    Gerard (89) is acceptable within 20db of reassigned
               pressure.

389 @1511db    Sample log: "Lid closed @ ~1570 by salt, Si, and T."
               Thermometric pressure, both Niskin (50) & Gerard salinities
               (89), and Gerard silicate indicate barrel closed at about
               1510db instead of the intended depth of 2242db.  The double
               ping came on time and all samples below were ok so the
               messenger released properly but the Gerard lid closed early
               or late.  Footnote bottle did not trip correctly. PB (50).
               Samples are good within 20 db of reassigned pressure.

344 @1741db    Sample log: "Came up no therm rack?"  Gerard (85) is
               acceptable.

385 @1742db    Gerard is acceptable, no temperature, see PB (44) comment.

142 @3301db    Delta-S(PB-G) at 3301db is 0.014, salinity is 34.672.
               Gerard (83) leaked.

183 @3301db    Sample log: "Didn't latch - o-ring again same as before."
               Delta-S(PB-G) at 3301db is 0.014, salinity is 34.672.  Data
               show leak on Gerard 83.  Footnote bottle leaking, samples
               bad. PB (42).

145 @3981db    Gerard (87) is acceptable. Temperature is ~0.04 high.
               Footnote temperature bad.

187 @3982db    Gerard is acceptable. Footnote temperature bad.  PB (45).

STATION 066

343 @1420db    Delta-S(PB-G) at 1420db is 0.02, salinity is 34.585.  Gerard
               salinity is low.  Could be a drawing error.  Let PI decide
               integrity of Gerard (85).

385 @1420db    Delta-S(PB-G) at 1420db is 0.02, salinity is 34.585.  Gerard
               salinity is low. Silicate agrees with rosette cast. Could be
               a drawing error.  Footnote salinity bad.  Let PI decide
               integrity of Gerard (85).  PB (43).

387 @1658db    Sample log:  "Messenger not released."  Gerard is
               acceptable, PB (44).  The remainder of the profile was done
               as Cast 4.

149 @4935db    Delta-S(PB-G) at 4935db is 0.004, salinity is 34.693.
               Gerard (94) may have leaked.  Gerard salinity is low,
               silicate looks reasonable.  Suspect there was a leak, let PI
               decide.

194 @4936db    Sample log: "Air vent open on return. Was definitely closed
               when deployed."  Gerard salinity is low, silicate looks
               reasonable.  Suspect there was a leak, let PI decide.
               Footnote bottle leaking, salinity bad.  PB (49).

STATION 076

Cast 1         Sample log: "Cast nominal. Thermometer malfunction."

389 @1588db    Sample log: "Therm rack 6 reversed on deck."  Temperature is
               lost.  Gerard salinity and silicate agree with rosette data.
               Gerard is acceptable, PB (50).

350 @1588db    Temperature is lost.  Gerard salinity and silicate agree
               with rosette data.  Gerard (89) is acceptable.

STATION 098

150 @ 617db    Delta-S(PB-G) at 617db is -0.014, salinity is 34.577.
               Thermometric Pressure 617 vs intended depth 3370db.  Water
               samples also from about 617db.  Footnote bottle pretripped
               and samples bad.  Gerard (88) appears to have leaked.

188 @ 617db    Sample Log: "Bad o-ring?  Would not pressurize; opened and
               reclosed, o-ring damaged."  Thermometric Pressure 617 vs
               intended depth 3370db.  Water samples also from about 617db.
               Lid o-ring cut, difficult to open lid.  Used 617 db as
               accepted pressure with water samples as is.  Footnote bottle
               did not trip correctly, samples bad.  PB (50).

393 @1894db    Delta-S(PB-G) at 1893db is -0.0592, salinity is 34.639.
               Salinity too high, but sil reasonable.  Footnote salinity
               bad.

145 @3117db    Delta-S(PB-G) at 3117db is -0.011, salinity is 34.677.  PI
               to decide integrity of Gerard (87).

187 @3118db    Delta-S(PB-G) at 3117db is -0.011, salinity is 34.677.
               Gerard salinity is high, SiO3 agrees with rosette data.
               Footnote salinity bad.  Have PI decide the integrity of
               Gerard samples.  PB (45).

STATION 121

289 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

290 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

293 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

294 (No Pressure)
               Sample Log: "Did not trip. Redone as cast 3."

350 @1921db    Gerard (89) is acceptable at reassigned pressure.

389 @1921db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (50).

347 @2220db    Gerard (90) is acceptable at reassigned pressure.

390 @2220db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (47).

348 @2534db    Delta-S(PB-G) at 2534db is -0.002, salinity is 34.664.
               Gerard (93) is acceptable at reassigned pressure.

393 @2535db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (48).

281 @2673db    Salinity bottle was broken before analysis could be
               performed.  Salinity lost.  Silicate is high compared to
               rosette data, but agrees with silicate from other Gerard
               casts (which are also higher than rosette data).  Suspect
               Gerard is acceptable.  PB (41).

349 @2864db    Delta-S(PB-G) at 2864db is 0.002, salinity is 34.675.
               Gerard (94) is acceptable at reassigned pressure.

394 @2864db    Sample Log: "Pretripped."  Samples are acceptable at
               reassigned pressure.  PB (49).

242 @2938db    Gerard (84) is acceptable, PB salinity is low.  Footnote
               salinity questionable.  Delta-S(PB-G) at 2938db is -0.004,
               salinity is 34.670.

445 @3282db    Sample Log: "Valve open."  Gerard (87) is acceptable.
               Delta-S(PB-G) at 3282db is -0.002, salinity is 34.680.
                APPENDIX C:  TUNES CALIBRATION FIGURES





G.5  P17C TUNES-1 FINAL REPORT FOR AMS 14-C SAMPLES
     (Robert M. Key)
     July 2, 1996


1.0  GENERAL INFORMATION

WOCE section P17C was the first in a series of three cruise legs referred 
to as "TUNES". Mizuki Tsuchiya of SIO was chief scientist for this leg. 
This report covers details of data collection and analysis for the small 
volume radiocarbon samples. The reader is referred to "Documentation for 
WOCE Hydrographic Program section P17C" by L.D. Talley and M. Tsuchiya as 
the primary source for cruise information. Of 121 stations, 29 were sampled 
for radiocarbon. The AMS station locations are shown in Figure 1* and 
summarized in Table 1.


Table 1: P17C Station Summary

                          Date                        Bottom
                  Station 1991  Latitude  Longitude  Depth (m)
                  ------- ----  --------  ---------  ---------
                    1     6/2   36.172    -121.737     557
                    5     6/3   35.548    -122.863    3403
                   10     6/5   34.582    -126.400    4682
                   14     6/7   34.585    -131.320    5135
                   17     6/8   34.598    -134.963    5129
                   20     6/9   33.065    -134.997    4761
                   23     6/10  31.532    -135.002    4562
                   26     6/11  30.033    -134.952    5181
                   34     6/14  26.040    -134.970    4571
                   38     6/15  23.998    -135.000    4851
                   42     6/16  22.037    -134.997    5225
                   46     6/18  19.982    -135.017    5257
                   50     6/19  18.000    -135.005    5183
                   53     6/20  16.500    -135.000    4849
                   57     6/21  14.462    -134.978    4983
                   60     6/22  13.002    -135.003    4907
                   63     6/23  11.503    -135.000    4893
                   66     6/24   9.965    -135.057    4811
                   70     6/25   8.000    -134.998    4743
                   73     6/26   6.523    -135.000    4638
                   76     6/27   4.992    -134.972    4578
                   79     6/28   3.517    -135.002    4311
                   86     6/29   2.000    -134.990    4510
                   92     6/30   0.990    -135.000    4260
                   98     7/1    0.003    -135.157    4317
                  104     7/3   -0.993    -135.002    4479
                  110     7/4   -1.973    -135.002    4435
                  118     7/5   -3.488    -135.002    4672
                  121     7/6   -5.008    -135.008    4658


14-C samples were additionally collected for measurement by the large 
volume technique on 9 stations (17, 26, 34, 46, 57, 66, 76, 98 and 121). 
AMS sampling was used for the upper thermocline and large volume sampling 
for the deep and bottom waters. Results for the large volume samples are 
reported in Key (1996).

2.0  PERSONNEL

14-C sampling for this cruise was carried out by Robert M. Key (Princeton). 
14-C analyses were performed at the National Ocean Sciences AMS Facility 
(NOSAMS) at Woods Hole Oceanographic Institution. Salinities and nutrients 
were analyzed by the SIO CTD group and the Oregon State Univ. group 
respectively. Key collected the data from the originators, merged the files, 
assigned quality control flags to the 14-C and submitted the data files to 
the WOCE office (7/96).

3.0  RESULTS

This 14-C data set and any changes or additions supersedes any prior 
release.

3.1  HYDROGRAPHY

Hydrography from this leg have been submitted to the WOCE office by the 
chief scientist and described in the previously mentioned report.

3.2  14-C

Most of the Delta-14-C values reported here have been distributed in a data 
report (NOSAMS, 1994). That report included preliminary hydrographic data 
and 14-C results which had not been through the WOCE quality control 
procedures. This report supersedes any previous 14-C data distributions.


Table 2: Summary of Replicate Analyses

                Sta-Cast-   Delta                Standard
                 Bottle     14-C    Err  Mean*a  Deviation*b
                --------   ------  ----  ------  ---------
                14-1-3       77.0   3.7    76.7    0.4
                             76.4   5.2           
                17-2-1       79.1   8.4    82.0    4.1
                             84.9   5.2           
                23-1-11c    -21.6   5.5   -10.1   16.3
                              1.4  18.3           
                23-1-16    -182.1   3.9  -172.9   13.0
                           -163.7   4.2           
                26-2-12     -32.6   4.2   -30.8    2.6
                            -28.9   4.9           
                42-1-7       98.2   3.1    97.0    1.8
                             95.7   3.2           
                46-2-16    -181.6   4.0  -187.8    8.8
                           -194.0   7.1           
                76-2-13     -92.8   3.3  -100.8   11.3
                           -108.8   7.3          
                __________________________________________
                *a. Error weighted mean reported with data set
                *b. Error weighted standard deviation of the 
                    mean reported with data set.
                *c. Only second run retained for data set


At this time 449 of 507 samples collected have been measured and reported. 
Replicate measurements were made on 8 of the samples. These replicate 
analyses are tabulated and summarized in Table 2. The table shows the mean 
and standard deviation for each set of duplicates. For these few samples, 
the average standard deviation is ±7.3 0/00. This precision estimate is 
approximately correct for the time frame over which these samples were 
measured. For a summary of the improvement in precision with time at 
NOSAMS, see Key, et al. (1996). In the final data reported to the WOCE 
office, the error weighted mean and the larger of the standard deviation 
and the error weighted standard deviation of the mean are given for 
replicate analyses.

4.0  QUALITY CONTROL FLAG ASSIGNMENT

Quality flag values were assigned to all 14-C measurements using the code 
defined in Table 0.2 of WHP Office Report WHPO 91-1 Rev. 2 section 4.5.2. 
Measurement flags values of 2, 3, 4, 6 and 9 have been assigned to date. 
Approximately 50 samples remain to be measured. Currently, the unmeasured 
samples are incorrectly coded with a flag value of 9 (no sample collected) 
rather than 1 (sample collected) or 5 (no result reported). The choice 
between values 2 (good), 3 (questionable) or 4 (bad) is involves some 
interpretation. There is very little overlap between this data set and any 
existing 14-C data, so that type of comparison was difficult. In general 
the lack of other data for comparison led to a more lenient grading on the 
14-C data.

When using this data set for scientific application, any 14-C datum which 
is flagged with a "3" should be carefully considered. My subjective opinion 
is that any datum flagged "4" should be disregarded. When flagging 14-C 
data, the measurement error was taken into consideration. That is, 
approximately one-third of the 14-C measurements are expected to deviate 
from the true value by more than the measurement precision. No measured 
values have been removed from this data set.

Table 3 summarizes the quality control flags assigned to this data set. For 
a detailed description of the flagging procedure see Key, et al. (1996c). 
As more of the Pacific data set becomes available, it is possible that some 
of these flag values may be modified. Any additional data received for this 
leg will be reported to the WOCE office as they become available.

Table 3: Summary of Assigned Quality Control Flags

                              Flag  Number
                              ----  ------
                                2    431
                                3      7
                                4      3
                                6      8

5.0  DATA SUMMARY

Figures 2-4* summarize the AMS 14-C data collected on this leg. Only Delta-
14-C measurements with a quality flag value of 2 are included in each 
figure. Figure 2 shows the Delta-14-C values with 2sigma error bars plotted 
as a function of pressure for the upper two kilometers of the water column. 
The most noticeable characteristic is the broad spread of the data in the 
upper 500m. This is primarily due to shoaling of isopycnals in the 
equatorial zone. This figure also clearly demonstrates the sampling 
strategy used during the TUNES legs. That is, AMS sampling was almost 
totally limited to the upper 1500 meters of the water column. Large volume 
Gerard barrel sampling was used to cover the deep and bottom waters. This 
strategy was chosen primarily because the collection cost for AMS 14-C 
samples is significantly less than for the Gerard technique. At the time of 
this cruise, it was known that the AMS technique was less precise than the 
large volume technique, however Figure 2* clearly demonstrates that AMS 
precision is easily sufficient to resolve the vertical gradients in Delta-
14-C, at least in the upper kilometer.

Figure 3* shows the Delta-14-C values plotted against silicate for samples 
from the upper 2 kilometers of the water column. The straight line shown in 
the figure is the least squares regression relationship derived by Broecker 
et al. (1995) based on the GEOSECS global data set. According to their 
analysis, this line (Delta-14-C = -70 - Si) represents the relationship 
between naturally occurring radiocarbon and silicate for most of the ocean. 
They interpret deviations in Delta-14-C above this line to be due to input 
of bomb-produced radiocarbon. Clearly, this relationship is not ideal for 
the P17C data set. The points in Figure 3* fall into two distinct groups. 
The first group falls below the line for silicate concentrations greater 
than approximately 50mmol/kg then slopes sharply upward for lower silicate 
concentrations. The second group has fewer points, but generally has a 
linear trend across the plotted silicate concentration range and is 
significantly above and steeper than Broecker's relationship. The first 
data grouping is from stations which are south of ~20°N. For these data, 
the break in the trend (Delta-14-C ~-100 0/00; Si~40 µmol/kg) occurs at 
approximately the same location as CFC-11 goes to zero. While CFC-11 
concentration may not be as good an indicator as tritium, the data is 
consistent with the break point being the zone to which bomb-produced 
radiocarbon has penetrated.

Figure 4* is an objective section (LeTraon, 1990) of the Delta-14-C 
distribution for the upper kilometer of the water column (Station 17-121). 
Obvious in the figure are the doming of the isopleths near the Equator and 
the subsurface location of the maximum Delta-14-C concentration for most of 
the section.


FIGURE LEGENDS:

Figure 1*: AMS radiocarbon station locations for WOCE cruise P17C (TUNES-1).

Figure 2*: AMS Delta-14-C results for P17C stations shown with 2sigma error 
           bars. Only those measurements having a quality control flag value of 
           2 are plotted.

Figure 3*: Delta-14-C as a function of silicate for P17C AMS samples. The 
           straight line shows the relationship proposed by Broecker, et al., 
           1995 (Delta-14-C = -70 - Si with radiocarbon in o/oo and silicate in 
           µmol/kg).

Figure 4*: Delta-14-C concentration in the upper kilometer of the meridional 
           portion of TUNES leg 1 (Stations 17-121; WOCE line P17C). Gridding 
           done using the method of Letraon (1990); all samples measured using 
           the AMS technique (Key, 1996a,b; Key, et al., 1996). For most of the 
           section the maximum concentration is found below the surface. 

* All figures are shown in PDF file.



6.0  REFERENCES AND SUPPORTING DOCUMENTATION

Key, R.M., P17C TUNES-1 Final Report for Large Volume Samples, OTL 
    Technical Report 96-2, 18pp., 1996a.

Key, R.M., WOCE radiocarbon program reports progress, WOCE Notes, 8(1),12-
    17, 1996b.

Key, R.M., WOCE Pacific Ocean radiocarbon program, Radiocarbon, submitted, 
    1996c.

Key, R.M., P.D. Quay and NOSAMS, WOCE AMS Radiocarbon I: Pacific Ocean 
    results; P6, P16 & P17, Radiocarbon, submitted, 1996.

LeTraon, P.Y., A method for optimal analysis of fields with spatially 
    variable mean, J. Geophys. Res., 95, 13543-13547, 1990.

NOSAMS, National Ocean Sciences AMS Facility Data Report #94-093, Woods 
    Hole Oceanographic Institution, Woods Hole, MA, 02543, 1994.

Peng, T.-H., R. M. Key and H. G. Östlund, Temporal variations of bomb 
  radiocarbon inventory in the Pacific Ocean, Marine Chem., submitted, 1996.

Talley, L.D. and M. Tsuchiya, "Documentation for WOCE Hydrographic Program 
    section P17C", unpublished WHP manuscript.




                    APPENDIX D  TUNES PROCESSING NOTES


TABLE OF CONTENTS

  1.    CTD Shipboard and Processing Comments
    a.  TUNES-1 / WOCE-P17C
    b.  TUNES-2 / WOCE-P17S/P16S
  2.    Cast Stops Longer Than 1 Minute
    a.  TUNES-1 / WOCE-P17C
    b.  TUNES-2 / WOCE-P17S/P16S
  3.    CTD Temperature and Conductivity Corrections Summary
    a.  TUNES-1 / WOCE-P17C
    b.  TUNES-2 / WOCE-P17S/P16S
  4.    Summary of TUNES CTD Oxygen Time Constants
  5.    Levenberg-Marquardt Non-linear Least-Squares-Fit Oxygen Coefficients
    a.  TUNES-1 / WOCE-P17C
    b.  TUNES-2 / WOCE-P17S/P16S


          TUNES-1  WOCE-P17C CTD SHIPBOARD AND PROCESSING COMMENTS

sta/cast  Comments
--------  ----------------------------------------------------------------------
999/01    TEST cast - not part of final data distribution; all btls tripped same 
          press.; dirty xmiss
001/01
002/01
003/01
004/01
005/01
006/01
007/01
008/01
009/01    wire jumped sheave/mangled at 20mwo, discovered/fixed at 60mwo; back 
          to 40mwo and restart cast: 33-min. delay; outer rosette did not trip: 
          no discrete oxygen values below 350db - used stas 8+10 bottles to 
          approximate deep ctdoxy fit
010/01    NEW END TERMINATION prior to cast; incrs. current slightly at 340db 
          down; bad/high raw ctdoxy from 0-12db - ctdoxy no good above 14db
011/01
012/01    deck unit lvl too high = crazy signal during trip/confirm time
013/01    CTD/Rosette hit bottom/stayed awhile; winch op noted heave compensator 
          stopped functioning near beg. of upcast: fixed; inner rosette did not 
          trip: no discrete oxy values above 350db - used stas 12+14 bottles to 
          approximate surface ctdoxy fit - ctdoxy no good above 40db
014/01    NEW END TERMINATION prior to cast, approx. 100 m wire cut off first; 
          down 200m after 3972db trip/winch op.error: unplanned yoyo; Raw ctdoxy 
          = 0 from 20-30db down - ctdoxy no good above 114db
015/01    yoyo back down at 2349db up to get skipped bottle; raw ctdoxy = 0 from 
          0-4db down - ctdoxy no good above 10db
016/01    UP cast; no vcr recording 800-1100db down: vcr power off, data lost
017/02    long pause at 15db to check computer problem; 11-min. stop at 20db 
          down; hi raw ctdoxy at surface - ctdoxy no good above 12db
018/01    slight data glitch each time bottle triggered: lowered DU level 
          partway thru upcast; raw ctdoxy = 0 from 0-14db down - ctdoxy no good 
          above 18db
019/01    raw ctdoxy = 0 from 0-12db down - ctdoxy no good above 20db
020/01    raw ctdoxy = 0 from 10-16 plus 24-34db down - ctdoxy no good above 
          54db
021/01    raw ctdoxy = 0 from 22-30db - ctdoxy no good above 42db; used some of 
          stas 20+22 deep bottles for deeper ctdoxy fitting: discrete values for 
          21 seem a bit high 022/01
023/01    no oxygen signal this cast
024/01    fixed ctdoxy sensor prior to cast
025/01    switch to pylon #2 on outer rosette
026/02    no vcr recording until 4587db up: pushed wrong button?
027/01    switch to pylon #3 on outer rosette; compensator problem/delay at 15m 
          down; xmiss signal crazy 370-775db down; ethernet hangup at 2680db 
          down: 1-hr delay; delay again at 800db up: finish cast w/o computer; 
          replayed from 815db up and merged raw data later
028/01    15-min. delay at start; xmiss bad to 1000db down
029/01    2020db (dn or up?) ethernet interruption/several minutes: "someone" 
          disconnected during cast
030/01    3500db down through up: xmiss signal all over
031/01    xmiss no good on upcast
032/01    xmiss signal went west at 3500db down
033/01    xmiss repairs attempted before cast
034/02    xmiss no good 3000db down and throughout up
035/01    xmiss no good below 2700db down; occas. ok after 3000db
036/01    xmiss goes wild below 800db down; 45-min. delay at 3553db up for winch 
          malfnct (wouldn't pull wire n): yoyod back down during repair then 9-
          min. delay at 3279db up to re-check
037/01    no xmiss: removed for repairs prior to cast
038/01    no xmiss
039/01    no xmiss
040/01    no xmiss
041/01    no xmiss; winch dropped ros. on rail, then to deck, during launch 
          (about 4 ft); no apparent damage to MTs/eqpt
042/01    no xmiss; 1-hr delay in start due to ship-power problems
043/01    no xmiss
044/01    no xmiss
045/01    no xmiss
046/02    xmiss back on: data goes haywire 4150db dn thru 3400db up
047/01    xmiss no good 450db dn thru 100db up
048/01    xmiss no good approx. 460db dn thru 100db up
049/01    xmiss signal PERFECT: Carl got it this time
050/01    -.004 salin offset at 2640db down, continues until gradual return by 
          about 2700db
051/01
052/01
053/01
054/01
055/01
056/01
057/02    winch counter problem: back to surface from 45 mwo, rezero, start back 
          down (never came out of water)
058/01
059/01
060/01    winch did not stop at btm when requested; 2m off btm at one point, 
          back up to 8m off for trip
061/01    yoyo? near 3915db trip/gave winch wrong depth
062/01
063/01    cast stopped approx. 10 minutes at 15 meters for compensator problem
064/01
065/01
066/02
067/01
068/01    delay cast start 15 minutes due to no PRT-2 signal: replaced cable
069/01    increased voltage from 16/17 to 25 approx 4265 rawdb (down?)
070/01
071/01
072/01
073/01
074/01    winch stopped 1640 mwo down: wire almost touching hull
075/01    winch stopped at 475mwo down due to engine problem
077/01
078/01
079/01    voltage check pre-cast/3000+db up = 25v
080/01    C-sensors kept wet w/saltwater regularly beg. this cast
081/01    LADCP cast, no xmiss/oxy/altimeter on CTD-2
082/01
083/01    LADCP cast, no xmiss/oxy/altimeter on CTD-2
084/01    20m overshoot at 364db trip, yo back
085/01    10-min. delay at start to add weights to rosette pkg
086/01
087/01
088/01    acquis. started before C-sensor cover removed: saltwater = thought it 
          was in water
089/01
090/01
091/01
092/01    overshot 422db btl by 40db, yo back
093/01
094/01
095/01    acquisition not started until after CTD in water -another pilot error 
          top 0-8db extrapolated
096/01
097/01    steamed west nearly 10 miles to avoid seamount/get deeper water
098/02    15-minute delay at start: computer problems.
098/04
099/01    all power to engines/CTD/computers/winch counter off while cast at 
          216db down; pkg dragged up to 147db due to huge wire angle; during 
          comp.boots, vcr on/winch back to surface to rezero; restart cast in-
          water, chopped off pre-outage data/re-avgd from near-surface restart
100/01
101/01
102/01
103/01
104/01
105/01
106/01
107/01    density invers. at base of mixed layer, 56-66db/-.035 total drop; 
          long/ continuous/ smooth: probably real
108/01
109/01
110/01
111/01
112/01    145db up: yo back to 312db: forgot to switch to inner pylon
113/01
114/01
115/01
116/01
117/01    vcr not turned on until 100db down
118/01
119/01
120/01    xmiss dropout area approx. 750-1300db down, ok after that: presume 
          "it" fell off
121/01
122/01    salt spike 2100db down (dropout/large): probable goop on sensor; big 
          spike 2084-2098 despiked; longer-lasting/smaller-size inversion 2174-
          2284 too big to despike
123/01

______________________________________________________________________________


           TUNES-2  WOCE-P17S/P16S CTD SHIPBOARD AND PROCESSING COMMENTS

sta/cast  Comments
--------  ----------------------------------------------------------------------
998/01    using CTD-1 from beginning of cruise. TEST cast: btls 20-36 all 
          tripped at 1000m; 3 additional btls tripped at 400m
124/01    repeat station 123 from leg 1
125/01
126/01
127/01
128/01    -.1 mmho/cm cond. spike at 148-152 db down; despiked/ok now
129/01    ABORT at 150m: sensor caps on/pinger off; data not saved
129/02    1-hr deploymt delay when rosette hit ship hard at initial launch: 
          weights knocked loose, CTD end clamp broken, other misc.breakage. No 
          cast# assigned to 2-minute first launch/data not used.
130/01    brief yoyo on down (15 to 12m) at base of T mixed-layer
131/01
132/02
133/01    frequent/high cond. noise (not drop-outs) on down from 810-1300 db, 
          again 1985-bottom; yoyo 50m back down after 2544 db trip to check 
          sensor response: problem occurs when P increases - cracked cell? yoyo 
          from 2546-2598 db up; 436,448,478 db levels interpolated: cutouts in 
          raw data signal.
134/01    replaced cond. cell with new spare prior to cast.
135/01    cond. problem may still be here, but smaller amplitude
136/01    cond. problem still here: maybe FSI temp board?
137/01    switch to CTD-2 beginning this cast
138/01
139/01
140/01
141/01
142/01    dipped into water before sensor covers removed/pinger on; trip inner 
          rosette first for freons
143/03
144/01
145/01
146/01    xmiss cleaned at start of cast
147/01
148/01    used PRT-1 for primary temperature during cast; used PRT-2 for final 
          data - see station 150 PRT comments
149/01    used PRT-1 for primary temperature during cast; used PRT-2 for final 
          data - see station 150 PRT comments
150/01    PRT-1 T offsets: +.7 deg at 528 db down and two smaller offsets. PRT-1 
          definitely sick; used PRT-2 for final data
151/01    CTD-10 starting here; trip detect only sees outer pylon: CTD data for 
          top 12 trips extracted manually
152/01
153/02
154/01
155/01
156/01
157/01
158/01
159/01    pauses at 2549/2742 db trips for winch operator work
160/01
161/01
162/01
163/01
164/01
165/02    inner pylon tripped first for freons
166/02
167/01
168/01    no well-defined mixed layer
169/01
170/01    stop at 1812 db down: winch trouble
171/01
172/02
173/01
174/01
175/01
176/01
177/01
178/01
179/02    cast start delayed 10 mins. after rosette hit side of ship: one 
          lanyard broken/repaired, no other damage noted.
180/02    xmiss check (before or after cast?)
181/01
182/01    ABORT at 100m down: complete signal loss; CTD-10 flooded
182/02    back to CTD-1 w/orig. C-sensor, changed shielding around PRT-2 
          temperature interface. Cond. problem worse: shorten cast to 2000m/24 
          btls. Cond. noise has pressure-direction (down) dependence, up much 
          cleaner. -.2 mmho/cm cond. spike 252-254 db up: despiked/ok now. 
          Multiple spikes on up cast, most despiked/ok now. Some smaller cond. 
          noise still remains. Yoyo from 294-330 db up.
183/01    back to CTD-2 using PRT-2 for primary temperature. No inner-pylon 
          detect circuit in: CTD data for top 12 trips extracted manually. 
          Ctdoxy signal cutouts top 120 db. Two DSRTs added to each cast from 
          here to end of cruise to monitor PRT drifting problems.
184/01    still no inner-pylon detect, CTD data for top 12 trips extracted 
          manually; ctdoxy signal cutouts top 70 db
185/01    pylon detect for inner pylon installed; ctdoxy problem fixed: sensor 
          interconnect cable problem.
186/01
187/02    ctdoxy probe acting up till 1900 db down
188/01    new oxygen sensor; PRT-2 jumped; cond. seems ok
189/01    ABORT at 300m: CTD-2/PRT-2 + cond. jumping; PRT-1 locked up at 32767 
          (raw data)
189/02    ABORT at 300m - similar problems to cast 1
189/03    rebuilt CTD-2: CTD-2 card cage in CTD-1 Pressure case w/turret, PRT, 
          endcaps, A/D, digitizer, mmux, P/T/orig.C sensors from CTD-1: still 
          cond. noise: low-side S noise from CTD-1 moved to CTD-2? Ctdoxy sensor 
          malfunctioning, reads 20% of normal values; ctdoxy data not usable. 
          Delay 27 minutes at 15m down: computer problems.
190/01    CTD-2 cond. sensor interface board swapped in, ctdoxy sensor wires 
          swapped; using CTD-1 tty/fsk card; ctdoxy still not working - see cast 
          189/03. Cast delayed 15 minutes for cable/connector repairs. Yoyo from 
          2968-2978 db up.
191/01    CTD oxygen useless again: see cast 189/03
192/01    CTD oxygen useless again: see cast 189/03; pinger died near bottom
193/01    delay cast start 40 mins.: replaced CTD-1 cond sensor interface. 
          Replaced ctdoxy sensor w/old one: ok. Yoyo from 2632-2642 db up.
194/01    TEST cast to <600m using CTD-2 P-sensor interface: no effect.
194/02    TEST cast to <600m using CTD-10 T-sensor interface: no effect.
194/03    CTD-1 P/T sensor interfaces. Same cond. noise as before.
195/01    experiments w/winch speed vs. cond. noise on downcast
196/01    found loose FSI-T bulkhead connector, tightened it: changed, but did 
          not eliminate, cond. noise: some stable cond. areas.
197/01    replaced FSI bulkhead/cleaned cond. sensor guard: coating on PRT/cond. 
          guard peeling off: large sheet still attached to top of guard: 
          apparently flapped over cond. cell going down, flapped out of the way 
          going up. Removed coating from guard: no more cond. problem!
198/02
199/01
200/01
201/01
202/01
203/01    rosette lowered into bottom (+8m after btm trip): winch went the wrong 
          way; no damage, but bottom cond. spike cut off in p-series. 1418 db 
          level interpolated: cutout in raw data signal.
204/01    NEW END TERMINATION prior to cast; steep btm/side of seamount
205/01    problem w/winch or heave compensator from 15m to 2233m
206/01
207/01    steep bottom
208/01    yoyo from 17-4 db down
209/01    -.5 mmho/cm cond. spike (seasnot?) 1056-1070 db down: despiked/ok now
210/02
211/01    1-hr delay at cast start: dead signal in-water, immed. back out: slip 
          ring plug slipped/plugged back in and insulation repaired. Second 
          false- start when cast resumed before computer ready. Data from false 
          starts not saved.
212/01    heave-compensator disabled 15-260m down as a test
213/01    bad/high ctdoxy rdgs up: water leaked into sensor
214/01
215/01
216/01
217/01    rosette briefly out of water before srfc btl closed; lowered back in
218/01
219/01
220/01    descent delayed 5 mins. due to heave compensator



TUNES-1: CAST STOPS LONGER THAN 1-MINUTE

Station  down  #minutes  avg.pressure  pressure
/cast    /up    stopped   (decibars)    range
-------  ----- --------  ------------  -------------
001/01   DOWN   4.8          20        (18 - 22)
                1.2         412        (410 - 414)
                7.3         516        (514 - 518)
002/01   DOWN   3.9          19        (16 - 22)
                1.1         912        (910 - 914)
003/01   DOWN   5.9          18        (16 - 20)
                1.6        1225        (1222 - 1228)
                1.5        1430        (1428 - 1432)
004/01   DOWN   5.5          20        (18 - 22)
005/01   DOWN   2.1           2        (0 - 4)
                5.8          18        (16 - 20)
                1.4        3446        (3444 - 3448)
006/01   DOWN   3.8          20        (18 - 22)
007/01   DOWN   4.1          20        (18 - 22)
                1.3        4228        (4226 - 4230)
008/01   DOWN   3.5          22        (20 - 24)
                1.0        4375        (4374 - 4376)
009/01   DOWN   4.1          20        (18 - 22)
               36.0          73        (68 - 78)
                1.8        4596        (4594 - 4598)
010/01   DOWN   3.5          22        (20 - 24)
                1.2        4767        (4766 - 4768)
011/01   DOWN   4.8          20        (18 - 22)
                1.1        4862        (4860 - 4864)
                1.3        4873        (4870 - 4876)
012/01   DOWN   2.7          22        (20 - 24)
013/01   DOWN   2.8          18        (16 - 20)
014/01   DOWN   1.8           2        (0 - 4)
                3.0          18        (16 - 20)
015/01   DOWN   3.3          20        (18 - 22)
016/01   UP     1.9          32        (30 - 34)
                1.0         208        (206 - 210)
                1.3        2022        (2020 - 2024)
                1.1        4082        (4080 - 4084)
017/02   DOWN  11.1          18        (16 - 20)
018/01   DOWN   1.2           3        (2 - 4)
                3.9          18        (16 - 20)
019/01   DOWN   3.3          18        (16 - 20)
                1.0        5114        (5112 - 5116)
020/01   DOWN   6.2          19        (16 - 22)
021/01   DOWN   1.2           2        (0 - 4)
                2.3          20        (18 - 22)
022/01   DOWN   5.3          18        (16 - 20)
023/01   DOWN   4.9          20        (18 - 22)
024/01   DOWN   3.4          18        (16 - 20)
025/01   DOWN   2.2          18        (16 - 20)
026/02   DOWN   4.8          18        (16 - 20)
027/01   DOWN   7.6          18        (16 - 20)
               59.3        2763        (2760 - 2766)

Station  down  #minutes  avg.pressure  pressure
/cast    /up    stopped   (decibars)    range
-------  ----- --------  ------------  -------------
028/01   DOWN   2.3          18        (16 - 20)
029/01   DOWN   3.6          20        (18 - 22)
030/01   DOWN   1.9          18        (16 - 20)
031/01   DOWN   2.8          18        (16 - 20)
032/01   DOWN   2.4          17        (14 - 20)
033/01   DOWN   4.0          18        (16 - 20)
034/02   DOWN   2.8          18        (16 - 20)
035/01   DOWN   2.6          18        (16 - 20)
                1.3        4610        (4608 - 4612)
036/01   DOWN   2.9          18        (16 - 20)
037/01   DOWN   2.7          17        (16 - 18)
038/01   DOWN   2.6          16        (14 - 18)
039/01   DOWN   3.4          18        (16 - 20)
040/01   DOWN   2.2          16        (14 - 18)
041/01   DOWN   3.2          18        (16 - 20)
042/01   DOWN   2.3          18        (16 - 20)
043/01   DOWN   3.0          18        (16 - 20)
                1.2        5174        (5172 - 5176)
044/01   DOWN   2.2          16        (14 - 18)
045/01   DOWN   2.6          16        (14 - 18)
046/02   DOWN   3.0          18        (16 - 20)
047/01   DOWN   2.3          18        (16 - 20)
048/01   DOWN   2.3          18        (16 - 20)
049/01   DOWN   1.8          18        (16 - 20)
050/01   DOWN   2.3          16        (14 - 18)
051/01   DOWN   1.9          17        (16 - 18)
052/01   DOWN   1.0           5        (2 - 8)
                3.1          18        (16 - 20)
053/01   DOWN   1.3          16        (14 - 18)
054/01   DOWN   3.3          18        (16 - 20)
055/01   DOWN   2.5          16        (14 - 18)
                1.2        4900        (4898 - 4902)
056/01   DOWN   2.1          18        (16 - 20)
057/02   DOWN   1.1          40        (38 - 42)
                6.4          48        (46 - 50)
058/01   DOWN   2.2          18        (16 - 20)
059/01   DOWN   1.6          16        (14 - 18)
060/01   DOWN   3.3          18        (16 - 20)
061/01   DOWN   2.3          16        (14 - 18)
062/01   DOWN   2.6          18        (16 - 20)
063/01   DOWN   7.6          18        (16 - 20)
064/01   DOWN   2.9          18        (16 - 20)
065/01   DOWN   1.8          18        (16 - 20)
066/02   DOWN   2.3          18        (16 - 20)
067/01   DOWN   2.3          18        (16 - 20)
068/01   DOWN   2.4          18        (16 - 20)
069/01   DOWN   2.1          16        (14 - 18)
070/01   DOWN   2.5          18        (16 - 20)
071/01   DOWN   2.6          16        (14 - 18)
072/01   DOWN   2.0          18        (16 - 20)
073/01   DOWN   2.5          26        (24 - 28)

Station  down  #minutes  avg.pressure  pressure
/cast    /up    stopped   (decibars)    range
-------  ----- --------  ------------  -------------
074/01   DOWN   2.8          18        (16 - 20)
                3.8        1619        (1614 - 1624)
075/01   DOWN   1.9          16        (14 - 18)
                5.9         479        (476 - 482)
076/02   DOWN   1.7          16        (14 - 18)
                1.0        4648        (4646 - 4650)
077/01   DOWN   2.2          16        (14 - 18)
078/01   DOWN   1.8          18        (16 - 20)
079/01   DOWN   2.0          16        (14 - 18)
080/01   DOWN   2.1          17        (14 - 20)
081/01   DOWN   2.3          18        (16 - 20)
                1.1        4386        (4384 - 4388)
082/01   DOWN   1.8          18        (16 - 20)
083/01   DOWN   1.8          18        (16 - 20)
084/01   DOWN   1.6          16        (14 - 18)
                1.1        4484        (4482 - 4486)
085/01   DOWN   2.0          18        (16 - 20)
086/01   DOWN   1.6          17        (16 - 18)
087/01   DOWN   2.0          18        (16 - 20)
088/01   DOWN   1.8          18        (16 - 20)
089/01   DOWN   1.9          18        (16 - 20)
090/01   DOWN   2.5          18        (16 - 20)
                1.7        4530        (4526 - 4534)
091/01   DOWN   2.4          18        (16 - 20)
092/01   DOWN   2.1          18        (16 - 20)
093/01   DOWN   2.0          18        (16 - 20)
094/01   DOWN   2.0          16        (14 - 18)
095/01   DOWN   2.9          18        (16 - 20)
096/01   DOWN   2.1          16        (14 - 18)
097/01   DOWN   2.1          18        (16 - 20)
098/02   DOWN  12.0          18        (16 - 20)
098/04   DOWN   2.0          20        (18 - 22)
099/01   DOWNÝ      
100/01   DOWN   1.7          18        (16 - 20)
                1.0        4285        (4282 - 4288)
101/01   DOWN   2.0          18        (16 - 20)
102/01   DOWN   1.9          16        (14 - 18)
103/01   DOWN   1.7          18        (16 - 20)
104/01   DOWN   1.6          17        (16 - 18)
105/01   DOWN   1.8          18        (16 - 20)
106/01   DOWN   1.8          17        (16 - 18)
                1.5        4406        (4404 - 4408)
107/01   DOWN   2.2          18        (16 - 20)
                1.5        4434        (4432 - 4436)
108/01   DOWN   1.9          18        (16 - 20)
109/01   DOWN   1.6          18        (16 - 20)
110/01   DOWN   2.1          18        (16 - 20)
111/01   DOWN   1.5          18        (16 - 20)
112/01   DOWN   1.8          16        (14 - 18)
113/01   DOWN   2.2          18        (16 - 20)
114/01   DOWN   1.8          18        (16 - 20)
115/01   DOWN   1.9          18        (16 - 20)
116/01   DOWN   1.6          16        (14 - 18)
117/01   DOWN   1.9          18        (16 - 20)

Station  down  #minutes  avg.pressure  pressure
/cast    /up    stopped   (decibars)    range
-------  ----- --------  ------------  -------------
118/01   DOWN   2.0          18        (16 - 20)
                1.3          50        (48 - 52)
119/01   DOWN   1.8          18        (16 - 20)
120/01   DOWN   1.6          18        (16 - 20)
                1.8        4709        (4706 - 4712)
121/01   DOWN   1.8          18        (16 - 20)
122/01   DOWN   1.7          18        (16 - 20)
123/01   DOWN   1.8          16        (14 - 18)

ÝNOTE:  No stops during 099/01: power outage during down cast. Package brought 
        back to surface without shutting down heave compensator; pressure-series 
        data taken from this second full down cast, no stops.


TUNES-2: CAST STOPS LONGER THAN 1-MINUTE

Station  down  #minutes  avg.pressure  pressure
/cast    /up    stopped   (decibars)    range
-------  ----- --------  ------------  -------------
124/01   DOWN    2.3          18        (16 - 20)
125/01   DOWN    1.9          18        (16 - 20)
126/01   DOWN    7.7           2        (0 - 4)
                 2.1          18        (16 - 20)
127/01   DOWN    3.5          18        (16 - 20)
128/01   DOWN    5.0          18        (16 - 20)
129/02   DOWN    1.9          18        (16 - 20)
130/01   DOWN    1.1           8        (6 - 10)
                 2.8          18        (16 - 20)
131/01   DOWN    5.1          18        (16 - 20)
132/02   DOWN    4.0          16        (14 - 18)
133/01   UP      1.6          16        (14 - 18)
                 2.7        2545        (2544 - 2546)
134/01   UP      2.0          16        (14 - 18)
135/01   UP      1.6           1        (0 - 2)
                 4.7          14        (12 - 16)
                 1.5         368        (366 - 370)
136/01   UP      1.8          18        (16 - 20)
                 1.7        2308        (2306 - 2310)
137/01   DOWN    2.3          17        (16 - 18)
138/01   DOWN    6.0          18        (16 - 20)
139/01   DOWN    1.9          20        (18 - 22)
140/01   DOWN    2.8          20        (18 - 22)
141/01   DOWN    2.0          18        (16 - 20)
142/01   DOWN    4.6           2        (0 - 4)
                 1.9          16        (14 - 18)
143/03   DOWN    1.4           4        (0 - 8)
                 2.4          21        (20 - 22)
144/01   DOWN    2.5          18        (16 - 20)
145/01   DOWN    1.8          20        (18 - 22)
146/01   DOWN    2.1          18        (16 - 20)
147/01   DOWN    1.9          20        (18 - 22)
148/01   DOWN    2.9          18        (16 - 20)
149/01   DOWN    1.6          20        (18 - 22)
150/01   DOWN    2.6          18        (16 - 20)
151/01   DOWN    1.8          19        (18 - 20)
152/01   DOWN    2.0          20        (18 - 22)
153/02   DOWN    2.9          18        (16 - 20)
154/01   DOWN    1.9          20        (18 - 22)
155/01   DOWN    2.0          22        (20 - 24)
156/01   DOWN    3.0          20        (18 - 22)
157/01   DOWN    2.1          20        (18 - 22)
158/01   DOWN    1.8          19        (18 - 20)
159/01   DOWN    2.2          22        (20 - 24)
160/01   DOWN    4.2          12        (10 - 14)
161/01   DOWN    2.3          22        (20 - 24)
                 2.2         503        (500 - 506)
162/01   DOWN    3.1          22        (20 - 24)
                 2.0         406        (404 - 408)
163/01   DOWN    1.8          22        (20 - 24)
                 1.3         498        (496 - 500)
164/01   DOWN    1.9          20        (18 - 22)
                 2.2         415        (412 - 418)
165/02   DOWN    2.3          20        (18 - 22)
166/02   DOWN    2.1          22        (20 - 24)
                 1.6         410        (408 - 412)
167/01   DOWN    1.7          21        (20 - 22)
                 1.2         410        (408 - 412)
168/01   DOWN    1.9          26        (24 - 28)
                 1.6         410        (408 - 412)
169/01   DOWN    2.2          20        (18 - 22)
                 1.2         547        (544 - 550)
170/01   DOWN    2.1          20        (18 - 22)
                 9.6        1822        (1820 - 1824)
171/01   DOWN    2.5          20        (18 - 22)
172/02   DOWN    2.0          20        (18 - 22)
                 1.2         426        (424 - 428)
173/01   DOWN    2.0          18        (16 - 20)
174/01   DOWN    2.5          22        (20 - 24)
175/01   DOWN    2.2          20        (18 - 22)
                 1.0         409        (408 - 410)
176/01   DOWN    1.9          20        (18 - 22)
177/01   DOWN    2.5          22        (20 - 24)
178/01   DOWN    1.7          22        (20 - 24)
                 1.3         412        (410 - 414)
179/02   DOWN    1.4           8        (6 - 10)
                 2.0          24        (22 - 26)
180/02   DOWN    1.3          19        (18 - 20)
                 1.1         442        (440 - 444)

Station  down  #minutes  avg.pressure  pressure
/cast    /up    stopped   (decibars)    range
-------  ----- --------  ------------  -------------
181/01   DOWN    1.8          22        (20 - 24)
                 1.8         405        (402 - 408)
                 1.1        5801        (5798 - 5804)
182/02   UP      1.4           2        (0 - 4)
                 2.0          16        (14 - 18)
                 2.6         293        (292 - 294)
                 1.8         510        (508 - 512)
                 1.5        2042        (2040 - 2044)
183/01   DOWN    2.1          20        (18 - 22)
184/01   DOWN    2.6          18        (16 - 20)
185/01   DOWN    2.0          22        (20 - 24)
                 1.4         515        (512 - 518)
186/01   DOWN    2.7          20        (18 - 22)
                 1.4         612        (610 - 614)
187/02   DOWN    2.1          18        (16 - 20)
                 1.1         394        (392 - 396)
188/01   DOWN    3.0          20        (18 - 22)
                 1.5         512        (510 - 514)
189/03   UPÝ     1.2           2        (0 - 4)
                 1.3          20        (18 - 22)
                 1.1         516        (514 - 518)
                 5.6        3094        (3092 - 3096)
                 5.4        4442        (4440 - 4444)
190/01   UPÝ     2.1          22        (20 - 24)
                 1.5         428        (426 - 430)
                 5.6        2968        (2966 - 2970)
                 5.5        4224        (4220 - 4228)
191/01   UPÝ     2.2           2        (0 - 4)
                 2.4          18        (16 - 20)
                 1.7         362        (360 - 364)
                 5.2        2924        (2920 - 2928)
                 5.4        4226        (4224 - 4228)
192/01   UPÝ     2.2          18        (16 - 20)
                 1.4          44        (42 - 46)
                 2.2         410        (408 - 412)
                 5.1        2717        (2714 - 2720)
                 5.4        4022        (4020 - 4024)
193/01   UPÝ     1.1           2        (0 - 4)
                 2.0          18        (16 - 20)
                 1.4         410        (408 - 412)
                 5.7        2632        (2630 - 2634)
                 1.7        3294        (3292 - 3296)
                 5.2        3818        (3816 - 3820)

Station  down  #minutes  avg.pressure  pressure
/cast    /up    stopped   (decibars)    range
-------  ----- --------  ------------  -------------
194/03   UPÝ     2.2          20        (18 - 22)
                 1.3         526        (524 - 528)
                 1.1        1432        (1430 - 1434)
                 5.4        2862        (2860 - 2864)
                 5.4        4164        (4162 - 4166)
195/01   UPÝ     1.2           1        (0 - 2)
                 1.9          18        (16 - 20)
                 1.9         404        (402 - 406)
                 3.4        2184        (2182 - 2186)
                 5.5        2800        (2796 - 2804)
                 7.0        3385        (3382 - 3388)
                 3.3        3439        (3438 - 3440)
                 5.8        3861        (3858 - 3864)
196/01   UPÝ     2.3          18        (16 - 20)
                 1.2         450        (448 - 452)
                 5.3        2674        (2672 - 2676)
                 5.3        3766        (3764 - 3768)
197/01   DOWN    4.3          18        (16 - 20)
                 1.1         410        (408 - 412)
198/02   DOWN    2.3          18        (16 - 20)
                 1.3        1657        (1654 - 1660)
199/01   DOWN    2.5          18        (16 - 20)
200/01   DOWN    1.8          18        (16 - 20)
                 1.0         512        (510 - 514)
201/01   DOWN    2.4          18        (16 - 20)
                 1.4         416        (414 - 418)
202/01   DOWN    1.7          18        (16 - 20)
203/01   DOWN    2.1          18        (16 - 20)
204/01   DOWN    4.8          24        (22 - 26)
205/01   DOWN   12.2          19        (16 - 22)
                 1.3         396        (394 - 398)
206/01   DOWN    1.6          18        (16 - 20)
207/01   DOWN    2.0          18        (16 - 20)
208/01   DOWN    2.1          18        (16 - 20)
209/01   DOWN    2.9          18        (16 - 20)
210/02   DOWN    1.8          16        (14 - 18)
                 1.2         408        (406 - 410)
211/01   DOWN    3.0          22        (20 - 24)
212/01   DOWN    6.5          17        (14 - 20)
213/01   DOWN    2.0          18        (16 - 20)
                 1.1         400        (398 - 402)
214/01   DOWN    1.8          18        (16 - 20)
215/01   DOWN    1.0          19        (18 - 20)
                 1.1         415        (414 - 416)
216/01   DOWN    2.2          18        (16 - 20)
                 1.1         444        (442 - 446)
217/01   DOWN    2.2          17        (16 - 18)
218/01   DOWN    2.8          16        (14 - 18)
219/01   DOWN    2.1          20        (18 - 22)
220/01   DOWN    6.2          18        (16 - 20)
                 1.2         420        (418 - 422)

ÝNOTE:  two 5-minute therm soaks on each UP CAST, stas. 183-220



TUNES-1: CTD Temperature and Conductivity Corrections Summary

         PRT   |                                    |      Conductivity
       Response|       Temperature Coefficients     |      Coefficients
Sta/     Time  |       corT = t2*T2 + t1*T + t0     |    corC = c1*C + c0
Cast    (secs) |     t2            t1          t0   |      c1         c0
------  ----   | -----------  ------------  ------- |  -----------  ------
001/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0093
002/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0093
003/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0093
004/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0123
005/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0108
006/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0128
007/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0118
008/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0108
009/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0096
010/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0064
011/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0101
012/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0109
013/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0107
014/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0105
015/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0102
016/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0060
017/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0098
018/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0041
019/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0093
020/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0091
021/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0049
022/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0086
023/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0114
024/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0102
025/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0080
026/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0047
027/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0045
028/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0073
029/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0051
030/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0068
031/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0046
032/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0046
033/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0047
034/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0047
035/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0048
036/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0048
037/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0049
038/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0069
039/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0050
040/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0050
041/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0051
042/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0051
043/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0052
044/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0052
045/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0053
046/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0053
047/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0054
048/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0054
049/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0055
050/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0055
051/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0056
052/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0056
053/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0057
054/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0057
055/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0058
056/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0058
057/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0059
058/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0059
059/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0060
060/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0060
061/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0061
062/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0061
063/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0062
064/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0062

         PRT   |                                    |      Conductivity
       Response|       Temperature Coefficients     |      Coefficients
Sta/     Time  |       corT = t2*T2 + t1*T + t0     |    corC = c1*C + c0
Cast    (secs) |     t2            t1          t0   |      c1         c0
------  ----   | -----------  ------------  ------- |  -----------  ------
065/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0063
066/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0063
067/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0064
068/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
069/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
070/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
071/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
072/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
073/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
074/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
075/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
076/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
077/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
078/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
079/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
080/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
081/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  8.86400e-04 -0.0445
082/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
083/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  8.64000e-04 -0.0478
084/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
085/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  8.41600e-04 -0.0350
086/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
087/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  8.19200e-04 -0.0403
088/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
089/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  7.96800e-04 -0.0456
090/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
091/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  7.74400e-04 -0.0353
092/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
093/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  7.52000e-04 -0.0396
094/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
095/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  7.29600e-04 -0.0404
096/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
097/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  7.07200e-04 -0.0366
098/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
098/04  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  6.96000e-04 -0.0428
099/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  6.84800e-04 -0.0334
100/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
101/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  6.62400e-04 -0.0367
102/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
103/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  6.40000e-04 -0.0364
104/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
105/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  6.17600e-04 -0.0337
106/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
107/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  5.95200e-04 -0.0325
108/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
109/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  5.72800e-04 -0.0352
110/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
111/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  5.50400e-04 -0.0315
112/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
113/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  5.28000e-04 -0.0308
114/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
115/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  5.05600e-04 -0.0300
116/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
117/01  .360   | 1.28600e-05  -7.32720e-04  -1.4935 |  4.83200e-04 -0.0293
118/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
119/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
120/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0078
121/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0068
122/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0068
123/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  3.44500e-04  0.0068


TUNES-2: CTD Temperature and Conductivity Corrections Summary

         PRT   |                                    |      Conductivity
       Response|       Temperature Coefficients     |      Coefficients
Sta/     Time  |       corT = t2*T2 + t1*T + t0     |    corC = c1*C + c0
Cast    (secs) |     t2            t1          t0   |      c1         c0
------  ----   | -----------  ------------  ------- |  -----------  ------
124/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0012
125/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0031
126/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0065
127/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0065
128/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0059
129/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0063
130/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0067
131/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0082
132/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0076
133/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  2.23244e-04  0.0080
134/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -3.80005e-02  0.0045
135/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -3.81843e-02  0.0111
136/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -3.83681e-02  0.0177
137/01  .360   | 1.28600e-05  -7.32720e-04  -1.5035 |  2.73821e-04 -0.0261
138/01  .360   | 1.28600e-05  -7.32720e-04  -1.5035 |  2.48147e-04 -0.0222
139/01  .360   | 1.28600e-05  -7.32720e-04  -1.5035 |  2.22472e-04 -0.0193
140/01  .360   | 1.28600e-05  -7.32720e-04  -1.5035 |  1.96798e-04 -0.0179
141/01  .360   | 1.28600e-05  -7.32720e-04  -1.5035 |  1.71124e-04 -0.0165
142/01  .360   | 1.28600e-05  -8.92720e-04  -1.5030 |  1.45449e-04 -0.0151
143/03  .360   | 1.28600e-05  -1.01272e-03  -1.5027 |  1.19775e-04 -0.0137
144/01  .360   | 1.28600e-05  -1.01272e-03  -1.5027 |  9.41008e-05 -0.0123
145/01  .360   | 1.28600e-05  -1.01272e-03  -1.5027 |  6.84265e-05 -0.0109
146/01  .360   | 1.28600e-05  -1.01272e-03  -1.5027 |  4.27522e-05 -0.0095
147/01  .360   | 1.28600e-05  -1.07272e-03  -1.5025 |  1.70779e-05 -0.0081
148/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  3.38337e-04 -0.0182
149/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  3.41332e-04 -0.0183
150/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  3.44328e-04 -0.0184
151/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  4.72316e-04  0.0004
152/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  4.60423e-04  0.0011
153/02  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  4.48529e-04  0.0023
154/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  4.36636e-04 -0.0000
155/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  4.24742e-04  0.0002
156/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  4.12848e-04  0.0004
157/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  4.00955e-04  0.0006
158/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.89061e-04  0.0008
159/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.77168e-04  0.0010
160/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.65274e-04  0.0012
161/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.53380e-04  0.0014
162/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.41487e-04  0.0016

         PRT   |                                    |      Conductivity
       Response|       Temperature Coefficients     |      Coefficients
Sta/     Time  |       corT = t2*T2 + t1*T + t0     |    corC = c1*C + c0
Cast    (secs) |     t2            t1          t0   |      c1         c0
------  ----   | -----------  ------------  ------- |  -----------  ------
163/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.29593e-04  0.0018
164/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.17700e-04  0.0020
165/02  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  3.05806e-04  0.0022
166/02  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.93912e-04  0.0024
167/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.82019e-04  0.0026
168/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.70125e-04  0.0028
169/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.58232e-04  0.0030
170/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.46338e-04  0.0032
171/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.34444e-04  0.0034
172/02  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.22551e-04  0.0036
173/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  2.10657e-04  0.0038
174/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.98764e-04  0.0040
175/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.86870e-04  0.0042
176/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.74976e-04  0.0034
177/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.63083e-04  0.0046
178/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.51189e-04  0.0049
179/02  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.39296e-04  0.0066
180/02  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.27402e-04  0.0063
181/01  .240   | 1.61680e-05  -1.21370e-04  -1.5021 |  1.15508e-04  0.0055
182/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -7.54052e-04  0.0222
183/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  4.43169e-04 -0.0220
184/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  4.46165e-04 -0.0221
185/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  4.49160e-04 -0.0242
186/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  4.52155e-04 -0.0224
187/02  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  4.55150e-04 -0.0225
188/01  .500   | 1.37930e-05  -4.90710e-04  -1.4844 |  4.58145e-04 -0.0226
189/03  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.39488e-04  0.0172
190/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  4.87559e-02 -0.0002
191/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  4.89572e-02 -0.0068
192/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 |  4.91585e-02 -0.0134
193/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -5.74023e-04  0.0146
194/03  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -5.57657e-04  0.0141
195/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -5.41291e-04  0.0156
196/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -5.24925e-04  0.0151
197/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
198/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
199/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
200/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
201/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
202/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
203/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
204/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
205/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
206/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
207/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
208/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0082
209/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0086
210/02  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0086
211/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0086
212/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0086
213/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0086
214/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0090
215/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0090
216/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0090
217/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0090
218/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0090
219/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0080
220/01  .325   | 1.93330e-05  -5.72760e-04  -1.4841 | -6.52178e-04  0.0090


SUMMARY OF TUNES CTD OXYGEN TIME CONSTANTS

       Oxygen  Casts            Temperature        Press.  O2 Grad.
       Sensor  Used       Fast(tauTF) Slow(tauTS)  (tauP)  (tauOG)
       ------  ---------- -----------------------  ----------------
       A       Leg1          32.0       363.0       19.4     60.0
       A/B     Leg2/Downs    32.0       363.0       19.4     60.0
       A       Leg2/UpsÝ     16.0       450.0       13.5    150.0

ÝNOTE:  pressure-series upcasts had an inverted elapsed time: 0 dbar times were 
        re-defined as 0, and other times were generated by subtracting averaged 
        time from averaged surface time. This required calculating entirely new 
        taus in order to fit the data.


TUNES-1 CTD Oxygen:  Levenberg-Marquardt Non-linear Least-Squares-Fit Coefficients

  Sta/|    Slope  |   Offset   |   Pcoeff   |   Tfcoeff  |   Tscoeff  |   OGcoeff
  Cast|    (c1)   |    (c2)    |    (c3)    |  (c4/fast) |  (c5/slow) |    (c6)
------|-----------|------------|------------|------------|------------|------------
001/01|7.24802e-03|-1.64874e-01|-5.88046e-04| 7.50834e-04|-2.29928e-01| 2.91662e-04
002/01|1.59970e-03| 2.30376e-02|-1.03207e-04| 8.18827e-02|-1.59326e-01|-1.66324e-03
003/01|3.15026e-04| 5.19964e-03| 7.51034e-04| 1.78011e-02| 5.06902e-02|-1.74772e-05
004/01|7.28075e-04| 1.79259e-02| 2.31249e-04|-1.12050e-02| 2.99172e-03|-5.14948e-04
005/01|8.66148e-04| 1.55705e-02| 1.78445e-04|-3.37323e-03|-1.65596e-02| 9.05355e-04
006/01|8.99873e-04| 1.04697e-02| 1.65530e-04|-1.72045e-02|-4.14432e-03| 6.32709e-03
007/01|9.95399e-04| 1.31497e-02| 1.47997e-04| 1.84243e-03|-3.36391e-02| 5.64380e-04
008/01|9.76694e-04| 1.77033e-02| 1.41771e-04|-4.73605e-03|-2.48935e-02|-2.11440e-04
009/01|9.56440e-04| 2.65778e-02| 1.37522e-04| 4.83369e-02|-7.45201e-02|-7.79174e-04
010/01|9.88382e-04| 2.24958e-02| 1.40405e-04| 1.60402e-02|-4.78611e-02| 1.03090e-04
011/01|1.13390e-03| 1.13424e-02| 1.23589e-04| 2.04578e-02|-5.86905e-02|-2.96790e-04
012/01|1.06528e-03| 1.00242e-02| 1.36141e-04| 4.39809e-03|-3.99916e-02|-2.03792e-03
013/01|1.09533e-03| 6.75918e-03| 1.26515e-04| 4.51826e-02|-7.65037e-02|-4.16009e-03
014/01|1.07251e-03| 8.60413e-03| 1.24851e-04| 1.38971e-01|-1.35022e-01| 6.97923e-03
015/01|1.03634e-03| 1.26313e-02| 1.36051e-04| 1.10361e-02|-4.22628e-02| 3.94571e-04
016/01|1.10259e-03| 1.19435e-02| 1.27983e-04|-1.31185e-02|-1.47817e-02|-1.77437e-02
017/02|1.07216e-03| 5.80046e-03| 1.35903e-04| 8.59448e-03|-4.07108e-02| 5.04564e-05
018/01|1.06536e-03| 8.52198e-03| 1.36759e-04|-7.69007e-04|-3.22740e-02| 2.19749e-04
019/01|1.02844e-03| 6.34713e-03| 1.46257e-04| 1.34253e-02|-3.92523e-02|-1.39068e-03
020/01|1.08031e-03| 1.06394e-02| 1.31171e-04| 1.74680e-02|-4.72440e-02| 8.04953e-05
021/01|1.00108e-03| 2.35202e-02| 1.33305e-04|-5.11347e-04|-2.92555e-02|-1.31592e-05
022/01|1.00705e-03| 8.12132e-03| 1.48304e-04|-5.21132e-03|-2.44990e-02| 1.43356e-03
024/01|9.90458e-04| 9.22801e-03| 1.50433e-04|-6.93736e-03|-2.65718e-02| 2.21753e-04
025/01|9.97056e-04| 1.16453e-02| 1.44410e-04| 7.84342e-03|-3.74745e-02| 2.94954e-05
026/02|1.03810e-03| 5.56055e-03| 1.40735e-04| 4.04221e-03|-3.62965e-02|-4.02753e-04
027/01|1.01856e-03| 8.29145e-03| 1.45002e-04| 2.24841e-04|-3.20108e-02|-1.72571e-04
028/01|9.70011e-04| 1.04460e-02| 1.50544e-04| 5.67253e-04|-2.79504e-02| 2.16493e-03
029/01|1.05468e-03| 7.92969e-03| 1.37816e-04| 3.81980e-03|-3.67238e-02|-1.81125e-03
030/01|9.49553e-04| 1.24023e-02| 1.59852e-04|-4.20201e-03|-2.23668e-02| 2.71781e-03
031/01|9.85060e-04| 2.58952e-02| 1.37944e-04| 3.77824e-03|-3.17873e-02|-5.48317e-04
032/01|1.03245e-03| 8.75749e-03| 1.39766e-04| 6.84639e-03|-3.64584e-02| 1.99483e-04
033/01|1.03076e-03| 1.36677e-02| 1.36592e-04| 6.32074e-03|-3.75352e-02|-4.11677e-04
034/02|9.82250e-04| 8.61063e-03| 1.52167e-04| 4.74635e-05|-2.86427e-02| 6.01967e-04
035/01|1.01850e-03| 8.53818e-03| 1.42389e-04| 3.56802e-03|-3.21076e-02| 5.37797e-03
036/01|1.04144e-03| 1.06440e-02| 1.36975e-04| 1.60627e-03|-3.38525e-02|-5.11363e-04
037/01|1.04224e-03| 8.09104e-03| 1.39074e-04| 6.00267e-03|-3.65478e-02| 1.93133e-04
038/01|1.03076e-03| 6.28557e-03| 1.41788e-04| 3.63026e-03|-3.27407e-02| 8.86588e-04
039/01|9.93443e-04| 1.32195e-02| 1.44250e-04| 6.18536e-03|-3.44103e-02| 2.59714e-04
040/01|9.58210e-04| 1.41796e-02| 1.51090e-04| 5.23193e-03|-2.99385e-02|-1.58064e-05
041/01|1.16584e-03|-2.82046e-03| 1.27278e-04| 8.75520e-03|-4.25786e-02|-1.12129e-04
042/01|1.03155e-03| 2.24784e-02| 1.30674e-04| 1.60939e-02|-4.49273e-02|-3.10167e-04
043/01|1.05447e-03| 1.81437e-02| 1.33218e-04| 1.78523e-02|-4.79855e-02|-9.99104e-04
044/01|1.08574e-03| 1.13440e-02| 1.32482e-04| 2.35363e-02|-5.30591e-02|-1.12824e-03
045/01|1.06818e-03| 1.03064e-02| 1.36599e-04| 1.16715e-02|-3.99727e-02|-5.14995e-04
046/02|1.00316e-03| 7.55728e-03| 1.48355e-04| 1.04310e-03|-3.08853e-02| 1.16109e-03
047/01|1.02483e-03| 1.06734e-02| 1.39914e-04| 1.21200e-02|-4.06460e-02| 3.79392e-04
048/01|1.00316e-03| 1.48015e-02| 1.42201e-04| 6.85070e-03|-3.47429e-02|-1.30695e-03
049/01|1.02951e-03| 1.30529e-02| 1.38424e-04| 5.41685e-03|-3.46088e-02| 6.31640e-04
050/01|1.00293e-03| 9.48351e-03| 1.47140e-04| 7.73951e-03|-3.55515e-02|-3.65630e-04
051/01|9.72054e-04| 1.86726e-02| 1.43866e-04| 1.83395e-02|-4.35549e-02|-1.26155e-03
052/01|9.70327e-04| 1.82255e-02| 1.45232e-04| 5.00731e-03|-3.22816e-02|-3.54447e-04
053/01|1.01009e-03| 1.08612e-02| 1.44849e-04|-5.18183e-03|-2.40106e-02| 1.70157e-03
054/01|9.75391e-04| 1.62491e-02| 1.45787e-04| 2.50062e-02|-5.10526e-02|-8.92685e-04
055/01|1.01451e-03| 7.39458e-03| 1.47500e-04| 2.40399e-03|-3.04572e-02|-2.53883e-03
056/01|9.84372e-04| 1.38237e-02| 1.47096e-04| 6.91325e-03|-3.32705e-02|-1.55152e-03
057/02|1.03037e-03| 8.38242e-03| 1.42387e-04| 7.76727e-03|-3.49248e-02|-2.81035e-04
058/01|9.69592e-04| 1.62891e-02| 1.49699e-04| 1.50016e-03|-2.96223e-02|-1.73616e-03
059/01|9.63017e-04| 1.05540e-02| 1.54861e-04|-1.25922e-02|-1.51927e-02| 2.31573e-03
060/01|1.02484e-03| 7.95632e-03| 1.42830e-04| 1.63860e-02|-4.35597e-02|-3.36013e-04
061/01|9.91187e-04| 1.30870e-02| 1.46085e-04| 1.80930e-02|-4.36226e-02|-2.54740e-03
062/01|1.01511e-03| 1.42072e-02| 1.40783e-04| 5.06870e-03|-3.47600e-02| 2.79641e-03
063/01|9.60282e-04| 2.20035e-02| 1.44553e-04| 3.13200e-02|-5.54393e-02| 1.43921e-03
064/01|9.67337e-04| 2.70884e-02| 1.38605e-04| 3.06649e-02|-5.54674e-02| 6.84215e-04

  Sta/|    Slope  |   Offset   |   Pcoeff   |   Tfcoeff  |   Tscoeff  |   OGcoeff
  Cast|    (c1)   |    (c2)    |    (c3)    |  (c4/fast) |  (c5/slow) |    (c6)
------|-----------|------------|------------|------------|------------|------------
065/01|9.64649e-04| 1.98868e-02| 1.44409e-04| 9.92911e-03|-3.49676e-02|-3.89444e-04
066/02|1.03870e-03| 1.07897e-02| 1.36764e-04| 2.80503e-02|-5.28224e-02|-2.05641e-04
067/01|9.85742e-04| 1.20290e-02| 1.46600e-04| 6.16394e-03|-3.22376e-02| 2.66969e-04
068/01|1.00534e-03| 1.81370e-02| 1.37677e-04| 1.30288e-02|-4.07731e-02|-1.14477e-03
069/01|9.94832e-04| 9.67186e-03| 1.48290e-04| 2.06267e-03|-2.82917e-02|-1.22294e-03
070/01|1.00110e-03| 1.07634e-02| 1.45605e-04| 5.16307e-03|-3.07097e-02|-1.01830e-03
071/01|1.00034e-03| 1.32691e-02| 1.44228e-04|-6.82664e-04|-2.66101e-02|-2.20217e-03
072/01|9.76264e-04| 1.47092e-02| 1.48223e-04|-7.18445e-03|-1.98852e-02| 1.39682e-03
073/01|9.42906e-04| 1.76837e-02| 1.50809e-04| 1.36076e-02|-3.51466e-02|-5.41324e-04
074/01|9.48056e-04| 1.58121e-02| 1.52092e-04| 3.09958e-03|-2.61022e-02| 1.77388e-03
075/01|1.02317e-03| 5.76000e-03| 1.45881e-04|-1.93653e-03|-2.40303e-02| 1.94567e-03
076/02|1.02695e-03| 1.97063e-03| 1.48249e-04| 5.29817e-03|-3.13972e-02|-1.33717e-03
077/01|9.66208e-04| 1.59690e-02| 1.48381e-04| 8.66840e-03|-3.27822e-02|-7.50186e-05
078/01|9.53351e-04| 2.03614e-02| 1.49489e-04|-2.20506e-03|-2.36307e-02| 1.60376e-03
079/01|8.44279e-04| 3.63518e-02| 1.60255e-04| 8.20097e-03|-2.79678e-02| 3.43004e-03
080/01|8.54124e-04| 4.18296e-02| 1.51174e-04| 4.77798e-03|-2.58247e-02| 1.65132e-03
082/01|1.00127e-03| 1.43549e-02| 1.44893e-04| 1.41171e-03|-2.76183e-02| 1.75646e-04
084/01|8.12746e-04| 5.58512e-02| 1.47347e-04| 2.72998e-02|-4.56791e-02| 6.91253e-04
086/01|9.87364e-04| 1.83455e-02| 1.43221e-04| 1.10180e-03|-2.65874e-02| 9.00150e-04
088/01|9.86015e-04| 1.66219e-02| 1.45459e-04| 1.07200e-03|-2.74424e-02| 7.95173e-04
090/01|1.00997e-03| 1.18297e-02| 1.43149e-04|-1.18376e-03|-2.70019e-02|-6.38732e-04
092/01|9.81762e-04| 2.08147e-02| 1.43329e-04| 5.52989e-03|-3.16522e-02| 8.92567e-04
094/01|1.01862e-03| 9.87764e-03| 1.44475e-04|-6.81784e-04|-2.68728e-02| 1.00537e-03
096/01|9.81805e-04| 1.40748e-02| 1.47398e-04| 4.11519e-03|-3.04472e-02|-4.03410e-04
098/02|1.00086e-03| 1.49427e-02| 1.42494e-04| 2.08308e-03|-2.88540e-02| 1.22995e-04
100/01|1.02141e-03| 3.96023e-03| 1.49361e-04|-5.75500e-03|-2.31526e-02|-2.76749e-04
102/01|9.85521e-04| 2.25166e-02| 1.40578e-04|-4.42452e-04|-2.66883e-02| 1.78573e-03
104/01|1.03763e-03| 8.35658e-03| 1.41275e-04| 6.19153e-03|-3.32475e-02|-2.98631e-04
106/01|8.99253e-04| 3.47073e-02| 1.49996e-04|-8.87613e-04|-2.34300e-02| 9.71442e-04
108/01|1.02563e-03| 1.53350e-02| 1.38094e-04| 1.33474e-03|-2.93419e-02| 1.23564e-03
110/01|9.29449e-04| 3.02655e-02| 1.46778e-04| 7.77714e-03|-3.07882e-02|-1.90474e-04
112/01|1.08311e-03|-4.59158e-03| 1.44577e-04|-3.46664e-03|-2.58978e-02| 1.25448e-03
114/01|9.31699e-04| 2.59204e-02| 1.52274e-04|-3.38423e-03|-2.16661e-02| 3.74394e-04
116/01|9.97384e-04| 7.41649e-03| 1.51550e-04|-8.25043e-04|-2.44237e-02| 8.58486e-04
118/01|9.44063e-04| 2.43379e-02| 1.48560e-04| 7.56279e-03|-3.20960e-02|-1.03462e-03
119/01|9.63304e-04| 2.74987e-02| 1.41882e-04| 4.87114e-03|-2.91449e-02| 1.49102e-03
120/01|8.47012e-04| 6.18122e-02| 1.37217e-04| 2.80281e-02|-4.84563e-02| 1.57515e-03
121/01|9.76510e-04| 1.14462e-02| 1.52606e-04|-6.87172e-03|-1.73796e-02| 3.55328e-03
122/01|9.06873e-04| 4.25844e-02| 1.39208e-04| 1.41900e-02|-3.72395e-02| 7.62275e-03
123/01|9.72822e-04| 2.56395e-02| 1.40124e-04| 6.35854e-03|-3.23910e-02|-1.80945e-04



TUNES-2 CTD Oxygen:  Levenberg-Marquardt Non-linear Least-Squares-Fit Coefficients

  Sta/|    Slope  |   Offset   |   Pcoeff   |   Tfcoeff  |   Tscoeff  |   OGcoeff
  Cast|    (c1)   |    (c2)    |    (c3)    |  (c4/fast) |  (c5/slow) |    (c6)
------|-----------|------------|------------|------------|------------|------------
124/01|9.74036e-04| 2.74161e-02| 1.38260e-04| 1.13660e-02|-3.74159e-02| 1.35937e-04
125/01|9.88555e-04| 1.42946e-02| 1.46805e-04|-8.23080e-04|-2.42034e-02| 2.32403e-03
126/01|9.64627e-04| 2.19085e-02| 1.46160e-04| 1.56478e-03|-2.69694e-02| 1.39288e-03
127/01|7.20499e-04| 9.55390e-02| 1.36654e-04| 2.30895e-02|-3.92416e-02|-8.73076e-04
128/01|7.85126e-04| 8.58324e-02| 1.29759e-04| 1.87087e-02|-3.71071e-02| 5.77933e-04
129/02|9.74450e-04| 2.45606e-02| 1.40970e-04|-2.42716e-03|-2.34322e-02| 4.75858e-04
130/01|9.72792e-04| 1.21977e-02| 1.51431e-04|-3.75316e-03|-1.88455e-02| 6.11484e-03
131/01|9.46839e-04| 2.20674e-02| 1.49447e-04| 2.02056e-03|-2.41925e-02| 7.48703e-03
132/02|8.69841e-04| 5.28195e-02| 1.40260e-04| 4.57305e-03|-2.52919e-02| 8.28663e-04
133/01|1.23075e-03|-3.70209e-02| 1.38253e-04|-3.38737e-02| 3.77030e-03|-4.45136e-03
134/01|1.16423e-03|-2.22803e-02| 1.41353e-04|-3.17152e-02| 3.43710e-03|-7.22666e-03
135/01|1.13587e-03|-2.13681e-02| 1.45314e-04|-4.15103e-02| 1.36212e-02|-1.44598e-03
136/01|1.14442e-03|-5.48818e-03| 1.30485e-04|-2.21766e-02|-5.84958e-03|-4.89250e-03
137/01|8.04538e-04| 8.80899e-02| 1.30294e-04| 1.79691e-02|-3.71009e-02|-3.46420e-04
138/01|9.27807e-04| 4.47543e-02| 1.39047e-04| 5.78485e-03|-2.93921e-02| 5.83201e-04
139/01|9.26000e-04| 5.28698e-02| 1.31956e-04| 5.99761e-03|-2.90277e-02|-3.67244e-04
140/01|9.72469e-04| 3.33778e-02| 1.39136e-04| 7.93609e-03|-3.19523e-02| 4.51678e-04
141/01|1.02034e-03| 2.82425e-02| 1.32970e-04| 8.15073e-03|-3.45033e-02|-6.18173e-04
142/01|8.78143e-04| 6.32930e-02| 1.34683e-04| 1.31040e-02|-3.30647e-02| 1.90743e-03
143/03|9.70027e-04| 3.39855e-02| 1.38869e-04| 6.13234e-03|-3.17918e-02|-5.63932e-04
144/01|9.97689e-04| 2.77420e-02| 1.37296e-04| 9.77747e-03|-3.55768e-02|-1.82198e-04
145/01|1.00357e-03| 2.01629e-02| 1.43201e-04| 7.79951e-03|-3.12180e-02| 7.34854e-03
146/01|1.00234e-03| 2.37381e-02| 1.41278e-04| 8.35470e-03|-3.40002e-02|-3.19773e-03
147/01|9.25596e-04| 4.63474e-02| 1.39812e-04| 5.32981e-03|-2.65962e-02| 6.16987e-03
148/01|9.43262e-04| 4.94159e-02| 1.32288e-04| 1.36087e-02|-3.74967e-02|-9.84955e-04
149/01|9.08413e-04| 6.01087e-02| 1.31258e-04| 7.29372e-03|-2.96914e-02| 3.04312e-04
150/01|1.13607e-03|-2.16355e-02| 1.49687e-04| 9.08542e-03|-3.85515e-02|-9.85967e-04
151/01|9.86250e-04| 2.35871e-02| 1.45587e-04| 5.27522e-03|-3.14749e-02|-2.00609e-03
152/01|9.79475e-04| 3.37289e-02| 1.35609e-04| 4.46854e-03|-2.88005e-02| 8.63516e-04
153/02|1.01440e-03| 2.98860e-02| 1.30338e-04| 4.92377e-03|-3.21539e-02| 1.42977e-03
154/01|9.56233e-04| 3.86116e-02| 1.36852e-04| 1.91465e-03|-2.75336e-02| 1.62430e-03
155/01|8.43446e-04| 8.20899e-02| 1.25023e-04| 7.79834e-04|-2.26916e-02| 1.00613e-03

  Sta/|    Slope  |   Offset   |   Pcoeff   |   Tfcoeff  |   Tscoeff  |   OGcoeff
  Cast|    (c1)   |    (c2)    |    (c3)    |  (c4/fast) |  (c5/slow) |    (c6)
------|-----------|------------|------------|------------|------------|------------
156/01|8.94453e-04| 6.14941e-02| 1.32899e-04|-9.68918e-04|-2.36078e-02| 5.26077e-04
157/01|9.83516e-04| 3.12903e-02| 1.37690e-04| 1.28305e-03|-2.82337e-02| 1.61909e-03
158/01|9.50178e-04| 2.48023e-02| 1.52902e-04|-2.84830e-03|-2.22188e-02| 5.00782e-03
159/01|1.10911e-03|-1.57433e-02| 1.45069e-04| 4.34918e-03|-3.42891e-02| 6.99069e-04
160/01|9.15838e-04| 5.65461e-02| 1.31994e-04|-2.82383e-03|-2.23812e-02| 1.50998e-03
161/01|9.76541e-04| 3.67686e-02| 1.35698e-04| 3.52564e-03|-3.03183e-02| 2.38863e-04
162/01|1.00913e-03| 2.18993e-02| 1.39440e-04|-4.99025e-04|-2.78230e-02| 5.73047e-04
163/01|9.92499e-04| 2.25870e-02| 1.44242e-04|-3.10614e-04|-2.63406e-02| 1.92347e-03
164/01|1.01372e-03| 2.01795e-02| 1.43503e-04|-1.18380e-03|-2.71355e-02|-2.37808e-05
165/02|9.47497e-04| 4.61054e-02| 1.34169e-04|-1.32815e-03|-2.50594e-02|-4.23704e-04
166/02|1.01222e-03| 1.16514e-02| 1.47535e-04|-3.01877e-03|-2.72148e-02|-1.62388e-04
167/01|9.65490e-04| 3.07138e-02| 1.43549e-04|-2.94021e-03|-2.46337e-02| 1.54298e-03
168/01|1.01952e-03| 9.38912e-03| 1.47524e-04|-3.31298e-03|-2.56856e-02| 9.19736e-05
169/01|9.92975e-04| 2.15173e-02| 1.45156e-04|-1.27772e-03|-2.66347e-02|-5.56928e-05
170/01|1.09682e-03|-4.67248e-03| 1.43783e-04| 4.33293e-03|-3.61059e-02| 4.13626e-04
171/01|1.03991e-03| 1.51834e-02| 1.41128e-04| 5.82635e-03|-3.48170e-02|-1.11327e-03
172/02|9.65464e-04| 2.88758e-02| 1.45327e-04|-1.07821e-02|-1.90955e-02| 1.17278e-04
173/01|9.92514e-04| 2.54707e-02| 1.43603e-04|-1.35774e-03|-2.64658e-02|-3.90692e-04
174/01|1.02221e-03| 1.61930e-02| 1.44875e-04| 6.18773e-03|-3.37413e-02| 1.07993e-04
175/01|9.70707e-04| 3.81207e-02| 1.40143e-04|-2.35929e-03|-2.45734e-02|-3.91433e-05
176/01|1.02346e-03| 1.71879e-02| 1.43864e-04| 1.61324e-03|-2.90824e-02| 4.25191e-04
177/01|1.00907e-03| 2.90049e-02| 1.38135e-04|-1.01364e-03|-2.58912e-02| 3.42700e-03
178/01|1.04821e-03| 1.43697e-02| 1.41951e-04| 4.73295e-03|-3.23759e-02| 2.37301e-04
179/02|1.03618e-03| 1.08475e-02| 1.47259e-04|-1.65927e-03|-2.70478e-02| 1.12468e-03
180/02|1.02725e-03| 8.05786e-03| 1.45292e-04|-2.51802e-03|-2.88875e-02|-5.86707e-04
181/01|9.83335e-04| 2.96404e-02| 1.39107e-04| 4.05513e-03|-3.04371e-02|-6.92337e-06
182/02|1.16887e-03| 7.62552e-03| 8.78018e-05|-2.61066e-02|-9.76593e-03|-3.77702e-03
183/01|1.00920e-03| 2.06813e-02| 1.43375e-04|-2.72462e-02|-8.78713e-03|-4.85355e-04
184/01|1.01351e-03| 1.73297e-02| 1.45849e-04|-2.66070e-02|-8.54734e-03|-1.03444e-03
185/01|9.39419e-04| 4.11220e-02| 1.41664e-04|-6.73055e-03|-1.73737e-02| 3.85836e-03
186/01|9.85708e-04| 2.94156e-02| 1.43114e-04|-5.15553e-03|-2.17635e-02| 1.91419e-04
187/02|9.93422e-04| 3.03151e-02| 1.40169e-04| 1.81920e-03|-2.85360e-02| 2.29725e-03
188/01|9.92379e-04| 1.83591e-02| 1.47224e-04| 3.31433e-03|-3.26159e-02|-4.28132e-06
193/01|8.56067e-04| 7.41068e-02| 1.31170e-04|-3.48618e-02| 1.45682e-02|-2.31530e-03
194/03|1.01673e-03| 3.30716e-02| 1.31019e-04|-2.48869e-02|-1.50489e-03|-6.41632e-03
195/01|1.03338e-03| 2.20898e-02| 1.36240e-04|-2.84714e-02|-8.76995e-06|-9.26474e-03
196/01|8.56847e-04| 8.00897e-02| 1.28120e-04|-3.22148e-02| 1.33820e-02|-1.04290e-03
197/01|9.98900e-04| 1.96720e-02| 1.45111e-04| 9.30220e-03|-3.71486e-02|-4.30105e-04
198/02|9.63034e-04| 3.00695e-02| 1.45933e-04|-1.22247e-03|-2.79709e-02|-1.23479e-03
199/01|8.90092e-04| 4.50071e-02| 1.53063e-04| 6.98631e-04|-2.34627e-02| 1.49480e-03
200/01|9.55612e-04| 1.96937e-02| 1.63588e-04| 6.05485e-03|-3.01778e-02|-3.26536e-04
201/01|9.61216e-04| 3.64178e-02| 1.44177e-04| 2.86506e-03|-2.95201e-02|-9.88325e-04
202/01|9.68779e-04| 3.78174e-02| 1.42125e-04| 2.10321e-03|-3.06230e-02|-2.12457e-03
203/01|9.75186e-04| 3.20391e-02| 1.46398e-04| 1.19479e-03|-2.91412e-02| 8.22370e-04
204/01|1.02167e-03| 2.29675e-02| 1.45919e-04| 4.17063e-03|-3.38061e-02|-1.29569e-03
205/01|8.53594e-04| 8.25995e-02| 1.33500e-04|-1.40165e-03|-2.17228e-02| 6.54864e-04
206/01|9.03648e-04| 5.93182e-02| 1.39662e-04|-2.76579e-03|-2.20259e-02| 1.93567e-03
207/01|9.40520e-04| 5.16192e-02| 1.37779e-04| 1.53863e-03|-2.76990e-02|-1.30542e-03
208/01|9.43210e-04| 4.38431e-02| 1.46352e-04| 1.69443e-03|-2.78140e-02|-3.41290e-03
209/01|8.57270e-04| 8.25120e-02| 1.32823e-04|-2.07116e-03|-2.15492e-02| 1.16307e-03
210/02|1.14233e-03|-1.64812e-02| 1.49065e-04| 1.36421e-02|-4.58470e-02|-5.32877e-03
211/01|1.02694e-03| 2.00706e-02| 1.45605e-04| 8.83728e-04|-3.02670e-02|-7.39584e-04
212/01|1.00621e-03| 2.79678e-02| 1.44059e-04| 6.48505e-03|-3.36940e-02|-1.57985e-04
213/01|8.38116e-04| 9.23205e-02| 1.27497e-04| 1.33727e-03|-2.28328e-02| 5.04368e-04
214/01|6.87475e-04| 1.37463e-01| 1.24238e-04|-1.92717e-03|-1.42103e-02| 7.51458e-04
215/01|9.26096e-04| 4.83288e-02| 1.47684e-04|-9.00041e-04|-2.46545e-02|-1.05974e-03
216/01|1.11954e-03|-1.04200e-02| 1.54310e-04| 9.97415e-03|-3.95453e-02|-1.27928e-03
217/01|1.02024e-03| 3.49490e-02| 1.42072e-04| 5.76715e-03|-3.22223e-02| 5.60629e-04
218/01|1.13903e-03|-1.62749e-02| 1.55528e-04| 3.12347e-03|-3.42289e-02|-7.74700e-04
219/01|7.96293e-04| 1.09757e-01| 1.29044e-04|-1.49413e-03|-2.03201e-02| 4.02498e-05
220/01|1.00456e-03| 3.96412e-02| 1.38775e-04| 4.36451e-03|-3.09871e-02|-7.55432e-04




WHPO DATA PROCESSING NOTES:

Date      Contact      Data Type           Data Status Summary
--------  -----------  ------------------  -----------------------------------
11/02/93  Mantyla      NUTs/S/O            DQE Report rcvd @ WHPO
              
12/13/93  Talley       NUTs/S/O            DQE Report sent to PI
              
04/07/94  Jenkins      He/Tr Shallow       Submitted for DQE
          The next message (1000+ lines) contains the tritium-helium 
          data for the TUNES 2 leg. Just to reiterate, this is the Thomas 
          Washington cruise that took place in the summer of 1991, covering 
          Pl7c-Pl6c along 135W and 150W respectively. The data are organized 
          as one line per "sample", which may contain tritium, helium or 
          both. -99 represents no data or sample for a variable. The columns 
          are as follows:
          
          Sta, Cast, Bottle, Pressure (db), tritium (TU), sigma-tritium 
          (TU), delta-3He (permil), sigma-delta (permil), conc-Helium 
          (nM/Kg), sigma-conc (nM/Kg), quall, qual2
          
          The quality numbers for tritium (quall) are
            1 =  valid sample
            2 =  possible under-extraction
            3 =  possible contamination
            7 =  identity suspected
            9 =  no sample
          In this data set, there were no quall values of 2,3 or 7
          
          The quality numbers for helium (qual2) are
            1 =  valid sample
            2 =  possible under extraction
            3 =  possible (air) contamination
            7 =  identity suspected
            9 =  no sample 
          In this data set, there were no qual2 values of 7
          
          Also, the obvious applies, if a sample value is null (-99) its 
          error, which may not appear as null (-99) is meaningless.
          
          Also, the tritium data has been corrected for a small (.0045 TU) 
          blank due to cosmogenic production during storage.
          
          Finally, I was hoping to finish up a paper that I am working on 
          for this data: I don't mind you using it for demonstration 
          purposes, but-I would hope that its distribution could be 
          restricted over the next 4-5 months until I have had a chance to 
          get it submitted and hopefully reviewed and accepted. Also, it 
          will give me a chance to make one final pass at the data to ensure 
          that there are no problems with it. I hope this is OK.
          
              
05/06/94  Joyce        He/Tr               Data Merged into BTL file  
          BTL file complete except for CFC's and CTDoxy
              
06/13/94  Talley       NUTs/S/O            PI Responded to DQE Report
              
Date      Contact      Data Type           Data Status Summary
--------  -----------  ------------------  -----------------------------------
01/13/95  Van Woy      CFCs                DQE Report rcvd @ WHPO
              
01/24/95  Van Woy      CFCs                DQE Report sent to PI
              
01/25/95  Tsuchiya     all                 OK to make Data Public
              
01/26/95  Millard      CTD                 DQE Report rcvd @ WHPO
              
01/27/95  Talley       all                 OK to make Data Public
              
07/01/96  Key          DELC14              DQE Report rcvd @ WHPO
              
03/04/98  Kozyr        CO2                 Final Data Rcvd @ WHPO
              
01/19/99  Willey       CFCs  Data rcvd @ WHPO  See Note:  I 
          received the CFC-11/12 datasets for the following WHP lines:
            EXPOCODE        31WTTUNES/2     WHP-ID  P17S,P16S
            EXPOCODE        31WTTUNES/1     WHP-ID  P17C
            EXPOCODE        316N138/12      WHP-ID  P19C
            EXPOCODE        318MWEST_4_5    WHP-ID P21E/W
            EXPOCODE        316N138/3       WHP-ID  P6E
          Each file looks fine and has been placed in the proper archived 
          directory on our machine so that they can be merged in with the 
          rest of the values.
          -Steve Diggs
          
          I just ftp'd our cfc files to the /INCOMING/RFine_cfcs directory.  
          The files named *.sea are hydro files with our final cfc values 
          and quality bytes merged in.  The files named *_cfcs.dat are files 
          that include station, cast, bottle, cfcs and quality bytes.  
          Please let me know if you have any problems and I'll let you know if 
          we have any changes (hopefully not...).
              
02/17/99  Bartolacci   CFCs                Data Merged/OnLine  
          P16s(31WTTUNES_2), p17c(31WTTUNES_1), and p19c(316N138_12) have all 
          had cfc data from Rana Fine merged and updated into them. The tables 
          and files have been updated to reflect this change. Data are public.
              
04/29/99  Bartolacci   DELC13              Data and/or Status info Requested 
          from P. Quay

10/08/99  Evans        DELHE3              Data Update
              
10/20/99  Willey       CFCs                Final Data Rcvd @ WHPO    
          This is 
          a follow-up to last month's message requesting that all of our 
          Pacific and Indian Ocean CFCs be made accessible to the public.  
          Our cruises are; (Pacific) P17C, P1716S, P06E, P19C, P17N, P21E, 
          and (Indian) I09N, I05W/I04, I07N, I10. 
              
Date      Contact      Data Type           Data Status Summary
--------  -----------  ------------------  -----------------------------------
01/18/00  Key          DELC14 LV           Final Data Rcvd @ WHPO  
          forwarded to Sarilee for reformatting  You may have tons of questions 
          regarding the following. Hopefully I can answer most of them. I 
          have tried to pare this listing down to a minimum at this point.
          
          Attached are 5 ascii files and one pdf file for P17C LV 
          (a.k.a.TUNES-1):
          
          P17CLV.data - my version of the final data file with all qc flags 
          (this file has a temperature flag (tf) and a pressure flag (pf). The 
          appendix to this report contains all shipboard notes regarding sample 
          collection, problems, etc.
            P17CLV.sta - my version of the final LV station file 
            P17CLV.pdf - my final data report for P17C LV data
            31WTTUNES1.ldo - original LV report produced by SIO (Sanborn)
            31WTTUNES1.lsu - final version of p17c lv sum file
            31WTTUNES1.lvs - initial version of p17c lv hyd file (no C14 prior 
                             to my QC, but close to WOCE format and with all 
                             times and locations)
            AND
          
          5 ascii files and 1 pdf file for P17C LV (a.k.a. TUNES-3). This 
          cruise was run by WHOI with 1 SIO Tech aboard to help with LV 
          work. As a result, no "official" hyd file was ever created. I got 
          P,T,S data from SIO, nuts from OSU, C-14 from Stuiver and Ostlund. 
          
            31WTP17C.doc  LV general info file from Talley
            31WTP17C.ps   Talley postscript cruise report for LV work
            31WTP17.lvs   original SIO P,T,S file 
            P16CLV.sta -  my final version of the LV station file
            P16CLV.data - my final version of the LV data file with C14, C13, 
                          nuts, and interpolated oxygen. I provided all final QC 
                          flags.P16CLV.pdf - my final report for this leg. 
                          Appendix includes decklog notes, etc. This document 
                          failed to get an official OTL report number or data (I 
                          use 1/31/97).
              
02/04/00  Kozyr        ALKALI/TCARBN       Final Data Rcvd @ WHPO; DQE Complete
              
06/21/00  Bartolacci   helium/delhe3       not yet merged into btl file
              
07/25/00  Johnson      DOC                 ODF Report rcvd @ WHPO  
          I transferred files over to the ftp-incoming directory the easy way 
          (for me)...  You will find the following "new" directories in 
          /usr/export/ftp-incoming on whpo:
              p16a_p17a
              p17c_p17s_p16s
              p17e_p19s
          I already gave you p19c (which I see is in P19Cdoc).  I thought it 
          was redundant to put long names in every filename, so I made the 
          directory name with the cruise lines, and the files are all the 
          same.  The figs files are all figxx.ps (where xx should indicate 
          the figure numbers referenced in the documentation).  I also 
          included ps and ascii versions of the original documentation and 
          applicable appendices.  (appendix a and b will be missing - they 
          are outdated now and shouldn't be included in anything.)
              
Date      Contact      Data Type           Data Status Summary
--------  -----------  ------------------  -----------------------------------
08/31/00  Anfuso       HELIUM/DELHE3       Data merged into online BTL file  
          Mergerd %deltaHe3 and molal[He] data into BTL file. Merging notes 
          in original subdir 1999.10.08_P17C_HE_LUPTON-EVANS. NOTE: 
          Merged over some existing (outdated) data at request of L. Evans 
          (see notes in 00_README file). Outdated helium data saved in 
          original directory as p17chy_rplcd_2000.08.31.txt.
          
          2000.08.31 SRA
          
          p17che_edt.dat: edited copy of p17woce.csv.txt. 
                          Replaced column delimiting ',' with spaces;
                          aligned columns for merging, 
                          replaced unreported data white space with
                             -9.0000 value for molal[He] on 
                                    sta/cst/btl: 
                                      25/1/26
                                      29/1/1
                                      31
                                      32
                                      41/1/27
                                      44/1/36
                                      61/1/30 
                                      65/1/18
                                      23
                                      33
                                      69/1/19
                                      28
          
          Runtime format: %delHe: a7,i6,a7,f10.2,i6 -->p17chy_delhe.dat
                          molal[He]: a7,i6,a7,16x,f11.4,i6 --
                                     >p17chy_delhe_he.dat
              
10/05/00  Anfuso       tcarbn, alkali      Data merged into online file  
          Merged TCARBN and ALKALI data into hyd file. Updated file is on 
          line. Merging notes in original subdir 1998.03.04_P17C_CO2_XXX.
              
12/11/00  Uribe        DOC                 Submitted  
          File contained here is a CRUISE SUMMARY and NOT sumfile. 
          Documentation is online.
          
          2000.10.11 KJU
          Files were found in incoming directory under whp_reports. This 
          directory was zipped, files were separated and placed under proper 
          cruise. All of them are sum files.
          Received 1997 August 15th.
              
02/06/01  Stuart       DELC13              Submitted
              
02/23/01  Huynh        DOC                 Website Updated; pdf version online
          Includes ODF report for legs 1-2, Appendices A-D, DQE reports 
          for CTD and Hyd (with a response to hyd DQE), SVC14 & LVS final 
          reports and data status notes.
              
02/26/01  Jenkins      He/Tr shallow        Data are Public
          It was brought to my attention that the WOCE PaciÞc/Indian He-Tr data 
          was not as yet made public. After submitting it to you last year, I 
          had intended on going through it one more time to ensure there were no 
          problems with it. Unfortunately, I have not had the time to do this. 
          Is it possible, therefore, to release it as public data, and if there 
          are any subsequent minor revisions, to make changes? I suspect there 
          might be a few samples in the set that might have got through our 
          initial quality control.
              
Date      Contact      Data Type           Data Status Summary
--------  -----------  ------------------  -----------------------------------
06/22/01  Uribe        CTD/BTL             CSV File Added to Website
          CTD and Bottle files in exchange format have been put online.
              
10/24/01  Bartolacci   CFCs                Data ready to be merged  CFCs ready 
          I have placed updated CFC data from Dave Wisegarver for 
          P17C in the original subdirectory in a the directory called 
          2001.07.09_P17C_CFC_UPDT_WISEGARVER.  notes, readme and data files 
          are located in this directory. data are ready for merging.
              
12/11/01  Diggs        CTD Updated         CSV File Added to Website
          Due to a flurry of messages, I have updated the CTD-Exchange 
          file using the "Diggs" v1.0e ctd-to-exchange code followed by the 
          rename_exctd.pl code. CTD-Exchange filenames *must*  be in the 
          standard form (p17c_XXSTN_XCAST_ct1.csv) for them to be zipped in 
          the proper order. New file placed online and checked with JOA3.0 
          under Mac OSX1.1.
              
12/19/01  Anderson     BTL/CFC/DELC13/SUM  Website Updated
          Data merged into online file, CSV file added, see note:
          Copied QUALT1 flags to QUALT2 flags. Checked to make sure Q2 
          were compatible with Arnold Mantyla's Q2 flags. Found Talley and 
          Tsuchiya's response to Mantylas DQ evaluation. Made changes to Q2 
          flags according to their response.
           
          Merged CFC's from Wisegarver (July 9, 2001) file. 
          Merged DELC13 received from Key (May, 2001) 
           Some minor reformatting of the .sum file to make it compatiable 
           with the accepted format.
          Converted to exchange format using new program.
           The new .sea, .sum, and exchange files put online.
          
              
03/28/02  Anderson     BTL                 LVS data converted to WOCE format 
          Bottle: (theta, salnty, silcat, nitrat, nitrit, phspht, revprs, 
          revtmp, delc14, c14err)
          
          Converted LVS data sent by Bob Key to WOCE format.  This file 
          needs to be linked to the web page.
              
Date      Contact      Data Type           Data Status Summary
--------  -----------  ------------------  -----------------------------------
06/07/02  Jenkins      DELHE3              Data Update 
          I don't believe we reported a station 29 bottle 1 for P17c. We 
          reported data for bottles 2,4,6,7,9,10,12 and 14 for that station. 
          Same issue for station 41. We didn't analyze a bottle 3 there. We only 
          reported data for bottles 2,4<=>16,18 and 19.
          
          By the way, negative values for del3He are certainly valid, and 
          should not be set to zero. Zero values for del3He may not 
          necessarily mean a problem, but I'll go through the numbers you 
          listed.
          
          We took some copper tube samples from station 123 (bottles 2<=>17) 
          on P17c. Although the samples were analyzed on the mass 
          spectrometer, the results were not processed appropriately (they 
          slipped through the net) yet somehow got included in the 
          submission. The best thing to do here is to eliminate them for the 
          atlas, and we'll see if we can recalculate them and resubmit them 
          later.
          
          Sample 121-1-8  (160.8 dbar)  was underextracted (procedural problem) 
                                        and should be eliminated.
          Sample 121-1-5  (110.8 dbar)  should be fine: the del3He = -0.004% 
                                        (thus was rounding to zero for you)
          Sample 116-1-4  (80.1 dbar)   was not analyzed by us (I don't know 
                                        how it got in the mix)
          Sample 110-1-9  (212.2 dbar)  was a failed analysis and should not 
                                        have been reported
          Sample 110-1-11 (310.3 dbar)  was not analyzed by us for helium
          Samples 80-1-X  (82-150 dbar) were not analyzed by us for helium (I 
                                        don't know why, but they weren't)
          Sample 65-1-4   (73 dbar)     wasn't analyzed by us for helium
          Sample 65-1-13  (610 dbar)    wasn't analyzed by us for helium
          Sample 54-1-8   (241 dbar)    was underextracted (procedural problem) 
                                        and should be eliminated
          Sample 48-1-7   (232 dbar)    wasn't analyzed by us for helium
          Sample 44-1-14  (601 dbar)    was underextracted (procedural problem) 
                                        and should be eliminated
          Sample 33-1-11  (300 dbar)    was underextracted (procedural problem) 
                                        and should be eliminated
          Sample 21-1-10  (253 dbar)    wasn't analyzed by us for helium
          Sample17-2-15   (699 dbar)    wasn't analyzed by us for helium
          
          In short, the only one from the bunch that should be kept is 121-
          1-5 (110.8 dbar). I'm sorry that the other rubbish somehow got 
          entrained in the file. I think it was one of my earlier submissions.
              
06/28/02  Anderson     LVS  Data Update    File converted to WOCE 
          format  Converted lvs fileP17CLV.data sent by Bob Key to WOCE 
          format. Found in p17c/original/2000.01.12_P17C_C14_Key
              
07/01/02  Uribe        LVS                 Website Updated  
          LVS data linked to web site 
    
 
09/03/02  Kappa       DOC                  PDF and TXT cruise reports updated
          Added CFC DQE reports from Van Woy and D. Wisegarver; these Data
          Processing Notes. Deleted Appendicies A & B as suggested by Mary 
          Johnson/ODF (see 7/25/00 above).  Added Large Volume Data Report
