Southampton Oceanography Centre
Cruise Report No.


RRS Discovery Cruise 223
28 September - 19 November 1996


Vivaldi '96


Principal Scientists
Harry Leach and Raymond Pollard


1998

Contents
Scientific Personnel

Ship's Personnel

1. Cruise Narrative
	1.1 Cruise Details
	1.2 Cruise Summary
		1.2.1 Cruise Track and Stations
		1.2.2 Equipment
		1.2.3 Sampling
		1.2.4 Number of Stations Occupied
		1.2.5 Floats Deployed
	1.3 Scientific Objectives
	1.4 Narrative
	1.5 Preliminary Results
	1.6 Major Problems and Goals not achieved

2. Continuous Measurements (on station and underway)
2.1 Navigation
2.2 Meteorological Measurements
	2.2.1 Main system
	2.2.2 Ship Calibration system
	2.2.3 Ship-borne Wave Recorder
2.3 Acoustic Doppler Current Profiler (ADCP)
	2.3.1 Calibration
	2.3.2 Standard Processing
	2.3.3 Backscatter
2.4 Acoustic Correlation Current Profiler (ACCP)
2.5 Thermosalinograph
	2.5.1 Temperature and Salinity
	2.5.2 Fluorescence
2.6 Shipboard Computing
	2.6.1 Level ABC System
	2.6.2 PSTAR System
	2.6.3 PSTAR Data Archive
2.7 Other Activities
2.8 Echosounding

3. On-Station Measurements
3.1 CTD
	3.1.1 Gantry and winch
	3.1.2 Equipment
	3.1.3 Data processing and calibration
	3.1.4 Oxygen calibration
	3.1.5 Reversing Thermometers and Pressure Meters
3.2 Chemical Tracer Studies
	3.2.1 CFC Sample Collection
	3.2.2 CFC Analysis
	3.2.3 Halocarbon Studies
	3.2.4 Halocarbon Sample Collection
	3.2.5 Halocarbon Analysis
3.3 Salinity Bottle Samples
3.4 Oxygen Bottle Samples
3.5 Nutrients Bottle Samples
3.6 Nitrate sensor
3.7 Oxygen Isotope Samples
3.8 Plankton Speciation and Pigment analysis
3.9 Chlorophyll Samples and Fluorescence Calibration
	3.9.1 Chlorophyll Determinations
	3.9.2 Fluorescence Calibration
3.10 Lowered Acoustic Doppler Current Profiler (LADCP)
	3.10.1 LADCP Processing for Current Profile
	3.10.2 LADCP Absolute Backscatter
3.11 Nets

4. Underway Measurements
4.1 SeaSoar
	4.1.1 Winch
	4.1.2 Deployment and recovery
	4.1.3 Equipment
	4.1.4 Data processing and calibration
	4.1.5 Salinity calibration
	4.1.6 Fluorescence Calibration to Chlorophyll
4.2 Optical Plankton Counter (OPC)
4.3 Continuous Plankton Recorder (CPR)
	4.3.1 Deployment
	4.3.2 Sampling
4.5 Underway Nutrients
	4.5.1 Samples
	4.5.2 Ultraviolet measurements
4.6 Sample Chlorophyll

5. Floats

6. Cruise Logistics

7. Cruise Diary

Tables

Figures

Scientific Personnel
									Leg:	L1	L2
LEACH, H.		Principal Scientist, Leg 1	Liverpool U		Y
POLLARD, R.T.		Principal Scientist, Leg 2	GDD, SOC		Y	Y
BACON, S.		ACCP, salinometer		JRD, SOC		Y	Y
BONNER, R.N.		SeaSoar, logistics		GDD, SOC		Y	Y
BOSWELL, S.M.		CFCs				GDD, SOC		Y	Y
DEUBERT, C.		HPLC				So'ton U		Y	Y
DUNCAN, P.		Computing			RVS, SOC		Y
FINCH, M.S.		Nutrients			GDD, SOC		Y	Y
GOULD, D.M.		SeaSoar, archiving		BODC, POL			Y
HARRIS, C.R.		CFCs				Liverpool U.		Y	Y
HARTMAN, M.C.		LADCP, backscatter		GDD, SOC		Y
HOLLEY, S.E.		Oxygens/nutrients		GDD, SOC		Y	Y
HOLLIDAY, N.P.		CTD/SS calibration		GDD, SOC		Y	Y
HUNTER, C.		Electronics			RVS, SOC		Y
JONES, J.L.		Mechanical engineer		RVS, SOC			Y
KENT, E.C.		Meteorology, SS, oxycal		JRD, SOC		Y	Y
KIRK, R.E.		CTD/SeaSoar electronics		OTD, SOC		Y	Y
LEE, M.-M.		sampling, oxycal		JRD, SOC		Y
NAVEIRA GARABATO, A.C. 	LADCP, chl, SS			Liverpool U		Y	Y
O'DWYER, J.E.		Navigation, ADCP		Liverpool U.			Y
MASON, P.J.		Mechanical engineer		RVS, SOC			Y
McCULLOCH, M.E.		Navigation, ADCP		Liverpool U		Y
MUSTARD, A.T.		Nets, chlorophyll		So'ton U		Y	Y
PAULSON, C.J.		Electronics			RVS, SOC			Y
RYMER, C.		Mechanical engineer		RVS, SOC		Y
SMITH, K.		Mechanical engineer		RVS, SOC		Y
SMITHERS, J. 		CTD/SeaSoar electronics		OTD, SOC		Y
SMYTHE-WRIGHT, D. 	CFCs				GDD, SOC		Y
TAYLOR, A.J.		Computing			RVS, SOC			Y
WATTS, S.F. J.		CTD				OTD, SOC			Y
WHITMARSH, V.G.		Irish Observer			U. Galway			Y
WINTERS, T.		Oxygen isotopes			U East Anglia		Y
YELLAND, M.J.		CFD Meteorology			JRD, SOC		Y

Ship's Personnel
HARDING, M.A.		Master
NODEN, J.D.		Chief Officer
WARNER, R.A.		2nd Officer
HOLMES, J.C.		3rd Officer
DONALDSON, B.		Radio Officer
BENNETT, I.R.		Chief Engineer
CROSBIE, J.R.		2nd Engineer
PHILLIPS, C.J.		3rd Engineer
CONNOR, K.M.		3rd Engineer
LEWIS, T.G.		CPO (Deck)
HARRISON, M.A.		PO (Deck)
ALLISON, P.		SG1A
BUFFERY, D.G.		SG1A
HEALEY, J.T.C.		SG1A
HEBSON, H.R.		SG1A
KESBY, S.		SG1A
BRIDGE, A.M.		POMM
STAITE, E.		S.C.M
SWENSON, J. J.E.	Chef
DUNCAN, A.S.		Mess Steward
ROBINSON, P.W.		Steward
OSBORN, J.A.		Steward

1. CRUISE NARRATIVE


1.1 Cruise Details
Expedition Designation: RRS Discovery Cruise 223, UK WOCE Cruise Vivaldi '96.
Co-principal Scientists: Dr Harry Leach (Liverpool) and Dr Raymond T. Pollard (SOC).
Ship: RRS Discovery.
Ports of Call: Falmouth via Reykjavik to Southampton.
Cruise Dates: 28th September to 19th November 1996 (with port call in Reykjavik 21st-22nd 
October).


1.2 Cruise Summary

1.2.1 Cruise Track and Stations

The cruise track with station positions is shown in Fig.1. Only small volume samples were 
taken, details are listed in Table 1. In Table 17 are listed the conversions of days of the year to 
conventional dates for the period of the cruise.


1.2.2 Equipment

The principal instruments used during the cruise were a NBIS Mark 3a CTD with oxygen sensor, 
transmissometer, fluorometer, in situ nitrate sensor, Simrad altimeter model 807-200m and IOSDL 
10 kHz pinger. These were mounted together with a multisampler rosette equipped with 24 10-
litre Niskin bottles. Two of these carried SIS digital reversing thermometers and one carried a 
reversing pressure meter. Upon recovery each bottle was sampled in turn for CFCs, dissolved 
oxygen, nutrients, salinity, oxygen isotope and the upper six bottles for chlorophyll analysis. All 
sampling was done on deck.

Between the CTD casts sections were worked with a SeaSoar (profiling CTD) carrying a NBIS 
mark 3 shallow CTD plus FSI conductivity cell and fluorometer. Data were collected from the 
upper 500m of the water column. Throughout the cruise the upper ocean currents (to about 300 
m) were measured with an RDI 150 kHz acoustic Doppler current profiler. Navigation 
information was provided by a Trimble GPS receiver supplemented by a Chernikeef 
electromagnetic log and Sperry gyrocompass. Ships position and attitude were also measured by 
an Ashtech 3D GPS system. Additional measurements were made with a Simrad echosounder, 
FSI thermosalinograph and fluorometer, IOSDL meteorological package, shipborne wave recorder. 
Experimentally an acoustic correlation current profiler was also used and in the Irminger Sea 
profiling floats were deployed.


1.2.3 Sampling

Nominal depths sampled were: bottom, 5500, 5000, 4500, 4000, 3500, 3000, 2750, 2500, 2250, 
2000, 1750, 1500, 1250, 1000, 750, 500, 400, 300, 200, 100, 75, 50, 25, 10m. On deep casts 
fewer shallow and intermediate bottles were fired. The maximum number of shallow bottles were 
fired to provide adequate coverage for interpretation of the chlorophyll data. Because of a 
shortage of Niskin bottles only 21 were used and this number was reduced to 19 in shallower 
water. The actual bottle depths are shown in Fig. 2.


1.2.4 Number of Stations Occupied

88 stations were occupied during the cruise (Fig.1). The first two CTD stations (12931 and 
12932) were worked as test stations and all the bottles were fired at depth. 8960 km of SeaSoar 
data were collected.


1.2.5 Floats deployed

Seven profiling "ALACE" floats were deployed in the Irminger Sea.


1.3 Scientific Objectives

The cruise objectives were to:
1. To complete a CTD section from Scotland to Iceland including the Rockall 
   Trough Section.
2. To survey the Subpolar gyre of the North Atlantic with high-resolution CTD 
   and ADCP data to determine the circulation of the upper waters.
3. To complement the shallow survey with a sparse, deep CTD survey (including 
   oxygen, nutrients, CFCs and oxygen isotope ratios).
4. To deploy profiling floats in the Irminger Basin.


1.4 Narrative

RRS Discovery Cruise 223, "Vivaldi'96", was a contribution to the UK WOCE Community 
Research Programme. The pattern of SeaSoar sections was designed to enable the upper ocean 
circulation in the Subpolar Gyre of the North Atlantic to be mapped and in particular the course 
of the North Atlantic and Irminger Currents within the region to be determined. The sparse deep 
CTD survey was required to complement the upper ocean survey and provide estimates of total 
mass transport and an "oceanographic opinion poll" of water mass properties, including CFCs.

The cruise commenced by repeating the well-established Rockall Trough CTD Section from Barra 
Head to Rockall Island. This was then extended north to Lousy Bank from where a CTD section 
measured before by Saunders across the Iceland Basin was repeated. From then onwards the 
cruise consisted principally of SeaSoar/ADCP sections interspersed with deep CTD casts (see 
track plot, Fig.1). These were placed on the "Vivaldi Grid" (round 3 of latitude and multiples of 
300 km west of 20W) where possible, though the complex topography was taken into account. 
East of Greenland a more intense CTD section of 6 stations (12995-13001) was made along 60N 
to cut the East Greenland Current. In addition 7 profiling floats were deployed in the Irminger 
Basin.



1.5 Preliminary Results

A first glance at the results seems to show that the principal branch of the North Atlantic 
Current proceeds northwards west of the Banks following the topographic slope on the east 
side of the Iceland Basin. On the east side of the Reykjanes Ridge flow in the upper waters 
appears to be southwestward and on the west side northeastwards not unlike the well-known 
deep flow in this region.


1.6 Major Problems and Goals Not Achieved

Bad weather caused the loss of 6 out of 20 working days during Leg 1.



2. CONTINUOUS MEASUREMENTS
   (on station and underway)

2.1 Navigation

Navigation data was converted from RVS format to PSTAR format in 12 hour segments using 
the following sequence of UNIX shell scripts:

navexec0: converted the RVS format navigation data into PSTAR format.

gpsexec0: converted DGPS navigation RVS format data to PSTAR format.
 
gyroexec0: converted the RVS format gyro-compass heading data into PSTAR.

ashexec0: read in heading (and attitude) RVS format data from Ashtech XII 3DF GPS receiver 
and converted to PSTAR format.

ashexec1: merged PSTAR Ashtech and gyro-compass data.

ashexec2: de-spiked Ashtech navigation data.

There were frequent, but usually short-lived gaps, in the DGPS data, due to poor satellite 
availability. In order to interpolate the DGPS heading data the available headings were plotted 
and spikes were removed before the values were interpolated over time.

Fig.3a shows the scatter of GPS positions in Falmouth; Fig.3b shows the DGPS scatter in 
Falmouth and Fig.3c shows the DGPS scatter in Reykjavik.

(M.E.McCulloch, J.E.O'Dwyer)


2.2 Meteorological Measurements

The usual mean meteorological measurements were supplemented by the addition of two fast-
sampling anemometers for measurement of the wind stress, and a "CFD" system which logged 
data from an array of anemometers. All systems were running immediately after departure 
from Falmouth on 28th September, and all worked reliably until completion of the cruise in 
Southampton on Tuesday 19th November.


2.2.1 Main system

The mean Meteorological instrumentation consisted of an augmented RVS system, logged via 
rho-point modules to a PC using the COTD software GrhoMet. The RVS sensors used were; 
a hull-mounted platinum resistance thermometer (prt) for sea surface temperature estimates, 
an aneroid barometer located in the main lab., and air temperature and humidity sensors, two 
photosynthetically active radiation (PAR) and two total irradiance (TIR) sensors and a Young 
propeller vane anemometer all of which were mounted on the foremast platform. The 
additional sensors supplied by COTD were; two psychrometers located on the foremast 
platform and two Epply long wave radiometers on the foremast extension. All instruments 
were sampled at 5 second intervals via the rho-point modules. Both raw and calibrated data 
were logged via the RVS level B as well as to the hard disk of the PC.

Logging of the mean met data to the RVS system was not completely reliable. Although the 
times logged to the files on the hard disk of the PC were regularly spaced at 5 seconds, the 
data received by the level B system contained different times at more irregular intervals. In 
particular between days 288 and 292 only two thirds of the data logged to the hard disk was 
received by the level B system. The reason for the drop in data quantity was not identified 
but the problem disappeared after a reboot of the mean met system PC.

Wind stress measurements: A Solent sonic research anemometer, mounted on the starboard 
side of the foremast platform, output 3 components of wind speed at a rate of 21 Hz. Four 10 
minute data sections were obtained every hour and logged to a PC in the plot. The logging 
software "fftset" also performed a spectral analysis of the data. The wind spectra and 
summaries of the spectral levels and mean wind speeds were backed up to the ship-board unix 
system, with the raw data being logged directly to optical disk. The spectral information was 
used to produce estimates of the drag coefficient or wind stress. For purposes of comparison, 
a second research anemometer was installed on the starboard arm of the main mast cross-tree 
and logged in an identical fashion to a separate PC, also located in the plot.

The meteorological conditions throughout the cruise are shown in Fig.9.


2.2.2 Ship Calibration system

An additional rho-point based system, similar to the GrhoMet system, was also installed. The 
CFD system sampled data, at intervals of 5 seconds, from a Windmaster Solent sonic 
anemometer boomed out from the port side of the foremast platform, and 5 Vector cup 
anemometers located on a 6m mast on the boat deck. Data were logged to a PC in the plot, and 
were backed up to the ship-board unix system via floppy disks. Data from the CFD system 
anemometers, the 2 research sonic anemometers and the Young propeller vane anemometer 
will be used to verify a computational fluid dynamics program ("Vectis"), which produces 
three dimensional simulations of the air flow over ships.


2.2.3 Ship-borne Wave Recorder

A ship-borne wave recorder (SBWR) was also installed and used to obtain one-dimensional 
wave spectra. Estimates of the average significant wave height over the 10 minute sampling 
period were obtained. Maximum significant wave heights recorded were greater than 13 
metres.
(M.J.Yelland, E.C.Kent)



2.3 Acoustic Doppler Current Profiler (ADCP)

2.3.1 Calibration

The positional accuracy of the DGPS system satellite fixes was assessed while the ship was 
stationary in port at Falmouth, where the data showed a scatter of less than 5 m. The ADCP 
recorded throughout the cruise with 64 bins, each 8 m thick, and a 2.5 minute sampling period. 
The transducer depth was 5 m and the blank-beyond-transmit length was 3 m. The first bin 
was therefore centred on 12 m depth. 
 
A zigzag calibration run (a series of eight 90-degree turns) was conducted between 6:30 and 
9:11 on 30th September (day 2 of the cruise) in bottom tracking mode west of Scotland. The 
bearing of the ship was varied between 15 and 105 degrees over 20 minute intervals, and the 
ship achieved each turn within 4 minutes. The ADCP water velocities relative to the ship 
were converted to east and westward velocities using the ship's heading from the gyro-
compass and these components were then recalculated using the, more accurate, ship's heading 
from the Ashtech 3DF GPS system. This correction was also applied throughout the cruise.
 
Using the water-tracking method of Pollard and Read (1989), and data from the zigzag 
calibration run, the misalignment angle between the ship's hull and the ADCP instrument was 
calculated as 3.57 degrees clockwise and the scaling factor was 1.0054. These values were 
confirmed using four bottom-track calculations. One calculation used bottom-track data from 
the ADCP obtained during the zigzag calibration run, and three other estimates were made 
using data from periods where the ship's heading and speed were constant over 77, 107 and 
192 km (or 5, 7 and 13 hours).
(M.E.McCulloch)


2.3.2 Standard Processing

ADCP data was converted from RVS format to PSTAR format in 12 hour segments. These 
segments were staggered 5 minutes back relative to the 12 hour navigation data to help with 
merging. The following sequence of UNIX shell scripts were used:

adpexec0: Converted RVS format ADCP data to PSTAR format. This script produced two 
files, one contained the speed of the sea floor relative to the ship (bottom tracking file) and the 
other contained a gridded file of velocities in the water column.

adpexec1: Every few hours the difference between the time on the ADCP PC clock (the time 
seen in the ADCP data) and the ship's clock (the time in the navigation files) was recorded. If 
the difference was greater than 2 minutes the ADCP clock was reset. The time difference was 
input to adpexec1 which then corrected the ADCP data file's times.

adpexec2: Merged ADCP data with Ashtech navigation data.

adpexec3: The values of the misalignment angle (phi) of the ADCP transducer and the 
amplitude factor (A) (both determined from the calibration runs near the start of the cruise) 
were hard-wired into this script, which then corrected the ADCP velocities. The script also 
averaged data within 15 minute intervals.

adpexec4: Merged ADCP data with the ship navigation data and so calculated the absolute 
water velocities from the ADCP relative velocities.

adpexec5: Produced postscript plots of the data.

adpexec6: Averaged the data on variable "distrun" to reduce data volume.

(M.E.McCulloch)


2.3.3 Backscatter

The Vessel Mounted ADCP can provide backscatter measurements in addition to the 
underway currents. The following paragraphs give a description of the data processing route 
used to achieve calibration of the acoustic backscatter. The method relies heavily on PSTAR 
programs run within shell scripts called execs, these are shown in quotes.

The exec 'ampexec' supplies parameters that are required to run 'ampexec0', 'ampexec2' and 
'ampexec4'. It prompts the user for an ADCP file number, start and stop times. 'ampexec' 
requires a clock drift correction file called 'times' that spans the ADCP file that is being 
created. It also needs a navigation file that spans the ADCP file. The file 'times' currently 
resides in the same directory as 'ampexec' while the navigation file is referenced via its full 
path name in 'ampexec4'. The script creates and maintains a file called lasttime which contains 
all of the ADCP file numbers and their respective start and stop times. The script 
'compressor' tidies the directory of files prior to amp223$num.rel by compressing them and 
putting them in a sub directory called 'arch'.

ampexec - ampexec0 - datapup pcopya pheadr pcopyg pcalib pcopya pheadr pcalib
	  file created; amp223$num bam223$num
	  
	  ampexec1 - ypstar pcalib parith pmerge parith pmerge parith
	  file created; aclock$num amp223$num.corr         
	  
	  ampexec2 - pcopya pedita adedit
	  file created; amp223$num.av         
	  
	  ampexec4 - pmerge adprl2
	  file created; amp223$num.abs

The reference level of the backscatter 'noise' was determined as follows; the ADCP data from 
CTD casts during yearday 275 (the output of 'ampexec') were copied into a PSTAR file. The 
variation of the ampl was plotted as a function of depth; the depth range where the 
backscatter signal had died away to a constant value was extracted using pcopyg (rows 59 - 
64). phisto was used to determine the average value of ampl. This was 7.5 dB, which at 0.42 
dB/count equates to 17.8 counts, but the lowest value of 7.2 dB was taken, equating to 17.14 
counts.

The values of K1 (=183.15) and K2 (=8.95) were derived from the Echo Intensity Logsheet 
supplied with the transducers (pers. comm. J.Wynar RVS) combined with the supply voltage 
(230.5V rms). The transducer depth was 5m and the electronics chassis temperature remained 
fairly constant at 222 C. These values were used to construct an ASCII file called 
amplcal.dat that is used by the program calamp3 in its determination of the absolute acoustic 
backscatter. Its contents are listed below:
 
4.17e5
183.15,8.95
21,11
8,8,5
17.14
1
	
The raw SeaSoar files ss223rxx were moved to the backscatter directory. Time must be 
monotonically increasing. The exec 'no_of_cols' takes an ADCP file and calculates the interval 
for gridding in the horizontal, then runs pgrids. The output from pgrids is used in pmergg 
where the temperature and salinity are merged onto the ADCP file. The output was inspected 
for periods of absent data and gaps interpolated with gintr2.

Once the variables temperature and salinity have satisfactorily been incorporated into the 
ADCP data file, values of ampl that are less than the background noise threshold (7.2 dB) 
were removed. Then calamp3 is run, this applies a calibration to the variable ampl, producing 
target strength Sv in dB. The new variable is called amplcal.
	
The data from periods where the CTD was deployed were saved as individual files and 
compared to the record from the lowered ADCP. This enabled a calibration to be applied to 
the lowered ADCP.
(M.C.Hartman)
A listing of the ADCP files is given in Table 13.


2.4 Acoustic Correlation Current Profiler (ACCP)

A new ACCP (or Correlation Sonar, CS) system was supplied by RD Instruments, the 
transducer for which was installed in the ship's hull by RVS divers in Falmouth during the 
pre-cruise mobilisation period. The sea chest is located in the winch room; the 41-core cable to 
the deck unit in the main lab had been installed on a previous cruise (Discovery 214). The 
most significant modification for our purposes over the previous installation was the 
incorporation of a gyro interface, so the output data streams included real-time ship's heading.

The deck unit consisted of the VM chassis and a Pentium PC with Panasonic optical disk. As 
networking does not yet exist as a facility on the CS system, the optical disk was used for 
data transfer to the ship's computer system. Desired files were copied from the PC to optical, 
which was transferred to a second, networked, PC. An additional complication was that it was 
not possible to run both the networking software and the optical driver on the second PC, so 
it was set up with two operational modes, one to see the Sun, one to see the optical (thanks 
Vic Cornell). The data were copied therefore from optical to the second PC's hard drive, the 
PC was then rebooted and the data copied to the Sun.

The system was supplied with correlation sonar version 1.08, DSP firmware version 2.23 and 
I860 software version 1.05. To translate recorded data files to ASCII, processing software 
(CSLIST) was supplied (version 1.00). Translation is rather slow: about 7 Mb per hour, 
where 7 Mb is about one day's worth of data. A problem identified early on with CSLIST was 
its inability to output bottom-track files. A fix was requested from RDI which was sent to 
Reykjavik (CSLIST 1.01) together with updated versions of various other elements of the 
DSP. Puzzlement over the system's reluctance to bottom-track in about 1000m water depth 
(well within its capability) resulted in further correspondence with RDI, who identified a bug 
in the DSP related to bottom velocity initialisation. A fix is being prepared for the next cruise 
(224). It was only possible to collect bottom-track data on the run home up-Channel, so such 
data as were collected were not able to be calibrated.

Operationally, the system was a disappointment. Very little useful data were collected, this 
appearing to be a result of the bad weather experienced during the cruise. Its effectiveness 
(proportion of good pings, depth penetration) was greatly reduced in all but the calmest 
weather, however. This will be investigated in greater detail at a later time, and will be 
described elsewhere. At RDI's request, bottom-level raw pings were collected before 
Reykjavik and sent on optical to RDI, who will investigate reported problems.

The PSTAR processing path, with execs modified from those developed during D214, was set 
up by Gwyn Griffiths in Falmouth, and further modified at sea to take account of the ASCII 
output format of CSLIST. Particularly, a new program, psecond, was written to convert 
CSLIST time (Y-M-D-H-M-S) and other output variables to seconds (plus variables) in 
PSTAR format.
(S.Bacon)


2.5 Thermosalinograph

2.5.1 Temperature and Salinity

Underway temperature, salinity, fluorescence and transmittance were continuously logged 
using the RVS surflog system. The equipment consisted of a Falmouth Scientific Inc. (FSI) 
remote temperature sensor mounted near the non-toxic intake in the forward hold, at a depth 
of 5m, and FSI conductivity and temperature sensors mounted in a polysulphanone housing in 
the hangar. A header tank was used to provide a constant flow of debubbled non-toxic water. 
Half-hourly or hourly calibration samples were taken from the thermosalinograph outflow, 
and header tank checks were made throughout the cruise. On 27 October (JDAY 301) it was 
noticed that the housing temperature sensor was producing suspect data and it was replaced 
with a new sensor. 

TSG salinity is usually calculated from the measured conductivity and temperature at the 
instrument housing located in the hangar (temp_h). The temperature of the surface water is 
measured by the remote sensor (temp_m). After the housing temperature sensor had been 
replaced, the data from Leg 1 was given a closer look and it was discovered that temp_h was 
consistently in error and hence unreliable for calculating salinity. The temp_h data from the 
original sensor drifted such as to be unrecoverable and so the next best option was to use the 
remote temperature to calculate salinity from the conductivity. Temp_m was calibrated with 
the surface SeaSoar temperature data and a linear offset (-0.01C) applied.

The hourly and half hourly bottle salinities from the non-toxic supply, plus surface bottle 
samples from CTD cast were used as true salinity from which to calculate an offset to be 
applied to the TSG salinities. CTD bottle samples were selected from a "master" sample file 
which consisted of all the appropriate sample files appended together. Datpik was used to 
select only CTD sample data from 0-10 dbars and this was further refined with pcopya to 
remove absent data, data with flags other than 2, and dcs where more than just the surface 
bottle from a particular cast had been selected. The CTD surface samples had their time added 
to the data file (pmerge), and were then merged with the underway samples. The file was 
sorted on ascending time (psort). 

The new salinity was calculated (peos83) and absolute salinity calibration was derived from 
the bottle samples. The data were merged on time and a linear regression used to derive A1 
and B1 coefficients (TSG salinity against bottle salinity). Prior to this, the difference between 
the bottle salinities and the TSG salinities was plotted to establish that there was no 
substantial drift with time or temperature. After calibration new residuals were calculated 
(parith) and the mean and standard deviation of the differences found with phisto. For Leg 1 
the mean offset was 0.0000 and the standard deviation 0.0338 for all data (252 data points) 
and mean -0.0006, sd 0.0231 for data within 0.05 (220 data points). For Leg 2 the mean 
offset was 0.0000, sd 0.0215 for all data (475 points) and mean 0.0015, sd 0.0114 for data 
within 0.05 (460 data points).

The salinity differences of the standards are shown in Table 15 and Fig.8.

(N.P.Holliday, M.-M.Lee, C.J.Paulson)


2.5.2 Fluorescence

Underway fluorescence during Vivaldi 96 was continuously recorded by means of a Chelsea 
Instruments Aquatracka III fluorometer mounted in a tank in Discovery's hangar. A steady 
flow of debubbled water was provided by a header tank in connection with the non-toxic 
intake in the forward hold, at a depth of 5 m. Reference to hourly bottle samples obtained 
from the same non-toxic intake allowed the conversion of the fluorometric measurements thus 
made to underway chlorophyll a concentration.

The calibration algorithm involved the calculation of fluorescence yield R, the ratio of 
fluorescence to chlorophyll a concentration, wherever a bottle sample had been taken. The 
parameter R is highly variable, depending on a wide range of factors such as phytoplankton 
species composition and physiological state, ambient light field or nutrient supply. Given the 
large-scale character of the Vivaldi 96 survey, the hourly bottle sampling rate was regarded as 
sufficient for resolving changes in R in any spatial scales coarser than that of the finest natural 
phytoplankton patchiness. The diurnal fluctuations in R associated with the ambient light 
field were also properly described by this sampling rate.

In order to smooth out the influence of the fine natural patchiness mentioned above, while 
accounting for small errors in bottle sampling times, the fluorescence yield R was gridded into 
a regular time grid (pavrge) and subsequently smoothed by using autocorrelation statistics 
(modified version of pcorr). Linear interpolation (pintrp) at sampling gaps finally provided a 
fluorescence yield function that was continuous over most of the time domain extending 
between the first and the last bottle samples on each leg. Only during storm events, with no 
bottle samples available, was R left undefined.

The estimation of the underway chlorophyll a concentration hence simplified to a trivial 
calculation (parith) of the ratio between the measured fluorescence and the local value of the 
fluorescence yield function. As a measure of the calibration error, figures of 0.97 for the 
correlation coefficient between bottle and thermosalinograph chlorophyll a concentrations and 
0.008 for their mean modulus relative deviation may be quoted. The mean modulus relative 
deviation is defined as

SN = (1/N) * _ |[chl(tsg)-chl(bot)]/chl(bot)| ,

with chl(tsg) = thermosalinograph chlorophyll a concentration, 
chl(bot) = bottle chlorophyll a concentration at the same sample point 
N = number of sample points
SN = summation over N sample points.


Archiving

The calibrated chl a concentrations averaged in 1 min bins for Leg 1 were stored in a file named 
tsg223.1min.chl and archived as tsg223.JC .

The equivalent file for the calibrated section of Leg 2 (since the beginning of the Leg till 
14.11.96 04:59:30) was called tsg223.2.1min.chl and archived as tsg223.2.FV .

(A.C.Naveira Garabato)


2.6 Shipboard Computing

2.6.1 Level ABC system

This was an unusual cruise from a computing perspective, with RVS supplying five 
workstations instead of the normal four, more disk space and the Hewlett-Packard XL-300 
A3 colour Postscript plotter from the RRS Charles Darwin swath bathymetry system. In 
addition to this many scientists brought their computer systems (and also two printers) on 
board which were successfully integrated into the ship's network.

Level A Systems
The Level A systems take data in an instruments native format, time-stamp it from the GPS 
based master clock, and convert it to the SMP (Ship Message Protocol) format, before sending 
it to the Level B system via a serial or network link.

There are four types of Level A computer in use on the RRS Discovery. Mk 1 systems use 
the 8 bit Intel 8085 processor and are the oldest computer systems still in use by RVS 
Information Systems Group. Mk II systems using the 16/32 bit Motorola 68000 processor 
were introduced in 1992 and have gradually been replacing the ageing Mk 1 systems. Mk II 
CTD Level A uses the 32 bit 68030 processor with a 68882 maths coprocessor and is 
specifically aimed at taking in sub-second CTD data and averaging it to give 1 second data. PC 
based Level A systems such as the Seametrix winch monitoring system are also in use.

Mk I Level A computers
	MX1107		-	Magnavox MX-1107 transit satellite navigator
	BOTTLES (see text)-	Tonefire rosette firing system

Mk II Level A computers
	LOG_CHF		-	Chernikeeff two component speed log
	GPS_4000	-	Trimble 4000DL GPS receiver with Skyfix corrections
	GPS_ASH		-	Ashtech 3DF attitude GPS
	GYROSYNC	-	Ship's gyro
	ANALOGUE	-	Three channel underway nitrate sensor
	BOTTLEM2(see text)-	Tonefire rosette firing system
	EA500D1		-	Simrad EA-500 echo sounder

Mk II CTD Level A computer
	CTD_12C & SEASOAR-	Neil Brown Mk IIIC CTD units for deep vertical 
				profiling and shallow towed profiling

PC Level A computers
	SURFLOG		-	Underway surface sampling
	GRHOMET		-	IOS met sensors
	WINCH		-	Seametrix cable metering system

The increased number of instruments on the CTD package ( 3.1.2) resulted in a new 
arrangement for logging the different variables. The oxyc variable was logged onto the channel 
previously used for the ftemp (fast temp), the three variables generated by the nitrate sensor 
were logged on 3 multiplexed channels, as was the altimeter and the CTD voltage data. 
However problems arose due to confusion over how the numbers of the CTD channels related 
to those logged on the Level A system (they have quite different numbering systems). After 
some time it became obvious that data from the altimeter was being incorrectly named as one 
of the nitrate sensor variables. The variable names were subsequently changed using the RVS 
stream header editor in existing data files, and the data grabber modified to ensure future casts 
were logged correctly.

The second problem involved the logging of the times at which bottles were fired. At the 
beginning of the cruise a Mk I Level A was being used for this. This ceased to work on Day 
??? and was replaced with the BOTTLEM2 application in a Mk II Level A. At Station 12984 
the last three bottle times were not logged, and none of the bottles were logged on the 
following cast. This was found to be a loose connection between the Level A I/O cable and the 
bottle-firer.

On day 285 there were periods of more than 15 minutes when none of the GPS receivers on 
board (including Koden GMDSS and RadioCode clock) could see any satellites. It is believed 
that this was due to an Aurora. The RVS gaps utility reports the following gaps.

time gap : 96 285 18:05:19 to 96 285 18:38:57
time gap : 96 285 19:59:08 to 96 285 20:24:19
time gap : 96 285 21:39:30 to 96 285 21:55:57 


Level B System
The Level B system worked well, only crashing once (and automatically rebooting itself), 
thankfully not during a CTD cast or SeaSoar run. The Level B's main function is to take all the 
data from the Level A computers and store it on tape as soon as possible. As well as doing 
this, it passes the data along the network (it can use a serial link if the network fails) to the 
Level C, provides a "First Look" system to check the data and keeps an eye on the Level A 
computers and alerts watchkeeper's if they stop sending data for longer than a specified 
period.


Level C System
The Level C system consists of a Sun SPARCstation IPC with 2 GB of local disk space. It 
takes data from the Level B and shipborne ADCP systems and stores it in RVS data streams 
format. The Level C's function is processing, display, and export of data to other systems 
such as PSTAR or MatLab. During this Leg several sets of processing were undertaken:

Log and Gyro data were combined to give a relative motion file by the relmov program. This 
data can then be used later on for dead reckoning when there is not Satnav or GPS fixes 
available.

Relmov data was combined with GPS data using the bestnav program to give a final navigation 
file with fixes, course & speed made good and distance run at thirty second intervals.
 
Echo sounder data was corrected for Carter area using the program.

CTD and SeaSoar data was processed from raw counts into real units.

The Level C system was also used to give a updating display of position for the CTD/SeaSoar 
operating position using a Falco terminal. A second terminal would have been useful as the 
CTD/SeaSoar operators also required winch and echo sounder data. This was eventually 
displayed on a laptop connected to a monitor, both of which were supplied by Chris Hunter 
of OSG.

The XL-300 A3 ink jet printer seemed to suffer from seasickness when the weather was 
particularly bad. This manifested itself with the printer indicating that its print carriage was 
jammed (all LED's flashing). During the period when the printer was not working, the Nicolet 
A0 plotter was used instead.

The A0 plotter was also used to produce large scale charts matching the scale of the 
commercially produced charts of the work area.

During SeaSoar runs the RVS bandplot program was used to produce a track of pressure (Y-
axis) against time (X-axis) with the colour of the track changing to indicate the temperature of 
the water through which the vehicle was passing. At the end of the runs a hard copy was 
produced on the Deskjet 1200C/PS.
(P.Duncan, A.Taylor)


2.6.2 PSTAR System

The PSTAR software system was used for almost all data processing. Details are given under 
the specific sections. A list of execs used in given in Table 2.


2.6.3 PSTAR Data Archive

During the cruise all the data could not be kept on-line at all times due to the lack of disk 
space. Data files were copied to a holding directory using a pexec shell script (arch_cp) ready 
for archiving. When sufficient data existed in this directory the files were copied onto two 
separate media - quarter inch cartridges and optical disks. Listings of the copied files were 
recorded for each cartridge and optical disk enabling any file to be easily located and retrieved 
when needed. After archival the copied files were deleted from the holding directory.

The cartridges used on the cruise were the Sony Data Cartridges QD6150 (150 Mb) and 
QD6250 (250 Mb), and the disks were the 5.25 inch 3M 1.3 Gb optical disks.

(D.M.Gould)


2.7 Other Activities

The Non Toxic System was in continuous operation for the duration of the cruise.

The Milli-RO/Q water production system was used throughout the cruise, during which time 
a carbon pre-filter was changed.

The engineering workshop facility was made available during the cruise. Various repairs, 
modifications and manufacturing were undertaken by the RVS staff.
(P.Mason, J.Jones)


2.8 Echosounding

The bathymetric equipment aboard during RRS Discovery Cruise 223 consists of a Simrad 
EA500 hydrographic echosounder, a Precision Echo Sounding (PES) towed 'fish' and hull 
mounted transducer Array. Data were collected from the PES fish located on the port side for 
most of the cruise, apart from periods prior to, or after docking when the Hull transducer was 
used.
 
The Hull mounted transducer is located 5.3 metres below the sea surface and this value was 
entered into the Transceiver Menu of the EA500 whenever it was used. In order to determine 
the depth of tow of the PES fish however, it was necessary to switch between the hull-
mounted transducer and the PES fish whilst hove to, over flat topography and in relatively 
calm conditions. This resulted in a fish depth below the waterline of 11.8 metres (this reduced 
to 9.5 metres at 8.0 knots typical SeaSoar towing speed). These measurements were made 
with the PES fish utilising a '30 metre' tow cable with one complete turn remaining on the 
drum and several metres used within the drum for the slip ring termination. It must be noted 
that a nominal 15 metres had been entered into the EA500 Transceiver menu for both Legs 1 
& 2 for PES fish deployments.

Data output consisted of a screen display, a continuous colour paper chart trace and serial 
data logged to the Level B/C via a Level A at a rate governed by the depth of water and the 
'sing around' time of the echosounder. Raw data were Carter corrected daily (prodep), suspect 
data flagged and the data placed in a Level B/C data file. Data were lost for a few minutes 
when the paper in the printer jammed causing the parallel printer port and subsequently the 
echosounder to 'hangup' resulting in a blank screen display. This condition was duly flagged 
by the Level B alarm monitor and reset by 'power cycling' the echosounder. 

Raw data were transferred to PSTAR format (datapup), zero values due to null returns from 
the echosounder removed using datpik, and averaged (pavrge) in 30 second intervals into a 
dep223nn.ave file. Further editing (mlist, peditb, plxyed) incorporated comparing the real time 
echosounder paper record with any suspect values due to side echoes or the echosounder 
losing lock over rapidly changing topography. Data were then rejected where the ships' speed 
was less than two knots and finally merged (pmerge) with navigation to produce a final 
dep223nn.nav file.

Two Master files dep223D1 and dep223D2 for legs 1 & 2 were created of all the edited, 
averaged and merged bathymetry. Separate files were also created corresponding to specific 
cruise sections with data increasing with longitude (psort) in order that bathymetry could be 
plotted for specific CTD sections:
 
	Rockall Trough				dep223RT
	Rockall Trough - Lousy Bank		dep223RL
	Lousy Bank - Iceland			dep223LI
	Iceland Basin				dep223IB
	Iceland - Irminger Basin		dep223II
	East Greenland Current			dep223GC
	Transect along 54 degrees North		dep223N4
	Transect along 57 degrees North		dep223N7

A listing of the depth files is given in Table 14.
 (C.Paulson)


3. ON-STATION MEASUREMENTS


3.1 CTD

3.1.1 Gantry and winch

The ten-tonne traction system was used to deploy the CTD package using the CTD 
conducting cable via the starboard gantry. This system was also used to deploy the plankton 
net to 500 metres on the CTD conducting cable.

The small auxiliary winch on the starboard gantry was used to deploy the plankton net to 
depths of 200 metres at each CTD station. During severe sea conditions the net was deployed 
outboard of the pendulum roller to guarantee a safe operation, preventing the weight swinging 
about or hitting the side of the ship.

The stability of the ship together with the handling capability of the starboard gantry allowed 
operations to continue for much of the cruise despite the appalling weather conditions.

(P.Mason, J.Jones)


3.1.2 Equipment

The deep profiler system used during the cruise included the following components:

Stainless steel, 24 bottle multisampler frame.
Neil Brown / General Oceanics Mk. IIIb CTD ( SOC modified ) DEEP01.
FSI 24 position Surefire Water Sampler ( SFWS ). 
SeaTech Transmissometer ( 1 metre pathlength ).
Chelsea Instruments Alphatracka MkII Transmissometer ( 25 cm. pathlength ).
Chelsea instruments Aquatracka MkIII Fluorometer.
SOC / Valeport Ultraviolet Nitrate Sensor.
RD Instruments Self-Contained Broad Band Acoustic Doppler Current Profiler (LADCP )
24 x 10 litre Niskin bottles.

Lab equipment for data acquisition and archiving of both CTD and SeaSoar data consisted of 
the following items mounted in shock resilient transport cases. One power supply and one 
data terminal were each dedicated to profiling and SeaSoar operations. 

Dual 486DX - 100 MHz. Personal Computers.
Dual Glassmann LV 300/3.5 DC Power Supplies ( 300v. / 3.5A.)
Dual FSI DT 1050 WS CTD Data Terminals.
OTD designed SeaSoar Controller / Deck Unit.



Cruise Preparation.

Preparation included modifications to the CTD instruments, rosette and multisampler frame. 
Special control and interface computer programs were written for use with the FSI pylons and 
the SeaSoar deck unit. 

Both Deep 01 and Deep 02 CTDs were fitted with redesigned pressure case end-caps to 
accommodate 6-way multipole Seaconnector Systems 'Pie' connectors, to allow power and 
signal connections to external sensors to be added. The end-caps also had an extra lip to ease 
their removal from the pressure cases for servicing purposes. Each instrument has been fitted 
with an 8 channel, 12 bit analogue to digital converter to digitise signals from external sensors. 
The data from converter is multiplexed sequentially into the 16 Hz. data stream, thus each of 
the d.c. analogue channels are sampled at a rate of 2 Hz. Instruments using the d.c. analogue 
facilities are, transmissometers (1 metre and 25 cm. versions ), fluorometer, altimeter and 
nitrate sensor ( 3 channels ).

A new FSI designed 24-way rosette pylon system and data demodulator unit were used for 
the first time on this cruise. The units had been tried once before but required modification by 
the manufacturers and at SOC to cope with the high current levels required by the deep 
profiling system and peripheral sensors. Special software was written to provide 
communication with, and display information from, the rosette pylon in a clear and 
convenient form. 

To enable the fitting of new sensors to the stainless steel profiling system frame all instrument 
support brackets were redesigned and fabricated prior to the cruise. New sensors were the 
nitrate sensor, a Chelsea Instruments 25 cm. pathlength transmissometer and RD Instruments 
LADCP with its separate battery pack pressure case. This LADCP in its short tube form was 
fitted centrally within the frame without requiring any extension of the standard height frame. 
Two complete sets of instrument power and signal cables were prepared for the new layout, 
prior to the cruise. 

Equipment and sensors were assembled before setting sail. Water bottles were checked for 
integrity of seals, taps, stoppers and lanyards before being fitted and roped to the 
multisampler frame.


Deployment

After sailing two shallow water casts were carried out to check the LADCP performance and 
check for water bottle contamination. The new FSI water bottle pylon fired all bottles without 
any problems. Following this, the cruise program of deployments proper began. 

CTD casts with the large multisampler frame and full set of sensors began to cause loading 
problems on the CTD cable when bad weather was encountered due to the drag of the 
package. This caused high peak loads which came close to the Rochester loading limit 
specifications. Two results of package drag in bad weather that occurred during the cruise 
were cable damage and loosening of water bottles. Several reterminations to the cable were 
made during the cruise to remove damaged cable, near the CTD rather than to replace failed 
electrical joints. On some deployments a few water bottles were shaken free of the frame 
mounts, but were retained by a safety line. Four bottles suffered damage to their lower fixing 
blocks and had to be replaced on the rig. Examination of bottles used during the cruise suggests 
dimensional variation between fixing blocks, making them more liable to working free, and lack 
of tension in some retaining pushrod springs.

CTD DEEP01 performed well during the cruise with little evident instrument drift and good 
accuracy. A loose water bottle fell onto the conductivity cell and snapped it off, but this was 
replaced without having to remove the sensor from the frame. The spare CTD DEEP02 was 
not required during the cruise.

The new 25 cm. pathlength transmissometer, fluorometer and altimeter gave good data 
throughout the whole cruise. Our old one metre pathlength SeaTech transmissometer was 
fitted to provide data for comparison with the new transmissometer. This unit was unreliable 
and data dropouts occurred during deployments. It was eventually removed from the profiler 
frame after enough data had been acquired for comparative purposes.

The LADCP fitted within the frame with a separate battery pressure case performed well and 
its performance and data are described fully elsewhere in this cruise report. This unit contains 
a compass and tilt sensors which could possibly provide useful information on the attitude 
and rotation of the whole profiler package throughout deployments. 

The three analogue signals produced by the ultraviolet nitrate sensor were digitised within the 
CTD by the 12 bit digitiser and the data multiplexed onto the CTD data frame. At one point 
in the cruise signals from this digitiser became very noisy and it was noticed that one analogue 
signal level generated by the nitrate sensor had risen beyond the full scale level for the digitiser 
input. As a result, the multiplexer for the digitiser carried excess charge from channel to 
channel causing spurious signal noise. The nitrate sensor was removed from the profiler frame, 
resulting in clean data on the other multiplexed auxiliary channels. The nitrate sensor was 
opened and a simple potential divider circuit ( 2 x 10k ohm resistors ) was added to the output 
of the overrange channel, to reduce the output level by a factor of two. When the sensor 
reinstalled on the profiler no further signal interference was seen throughout the rest of the 
cruise. 

Bottle firing using the new FSI deck unit and pylon was very reliable during the cruise. The 
pylon has individual solenoid release catches, rather than a rotary solenoid arrangement used 
on GO pylons for many years. This built in duplication prevents a simple mechanical fault 
having a disastrous effect on a bottle firing sequence. Predeployment set-up of the release 
catches and bottle lanyards is now both easy and positive. Electrical noise spikes on the CTD 
cable did cause some corruption of the pylon memory, resulting in incorrect responses 
occasionally, however it was always possible to fire bottles by individually addressed 
commands.

Operationally this has been a successful cruise with virtually no time being lost due to 
mechanical or equipment failure.
(R.Kirk, J.Smithers, R.Bonner, S.Watts)



3.1.3 Data processing and calibration

CTD data were logged at 16 frames per second and passed from the CTD deck unit to the 
Level A processor where they were averaged to one datacycle per second. At the Level A the 
rate of change of temperature was calculated and a median sorting routine used to detect and 
remove pressure jumps exceeding 100 raw units (approx. 10 dbars).

The 1 second data were transferred to PSTAR format (datapup) and calibrated (ctdcal) with 
coefficients from laboratory calibrations. The down cast was extracted (pcopya) and a file of 
10 second averages created (pavrge) for merging with the bottle firing times and discrete bottle 
samples.

Initial calibrations to the 1 second raw data were as follows:

Pressure = ((praw * 0.1) * 0.996263) + ((praw * 0.1)2 * 0.005743) - 0.93832

Pressure should have been corrected for the effects of temperature but it was not, leading to a 
small error.

The upcast portion of the file (data after the maximum raw pressure) were corrected for the 
differences between the upcast pressure calibration and downcast calibration (hysteresis). The 
adjustment was based on laboratory measurements of the hysteresis and was linearly 
interpolated between the values shown in Table 3.

For casts less than 5500 dbar the correction is automatically adjusted so that it is zero at the 
maximum pressure (P is pressure from CTD upcast):

Pressure = P - (dp5500(P) - ((P/Pmax) * dp5500(Pmax))


The temperature calibration applied was:

Temperature = Traw + _Traw * 0.20

where 0.20s is the time constant used to reduce the mismatch between the response time of 
the temperature and conductivity sensors as described in the SCOR WG51 report (Crease et 
al 1988). _Traw is the change in temperature over one second calculated by the Level A.

Then the polynomial expression from laboratory tests was applied:

Temperature = -0.0165549 + (T * 0.000499282) + (T2 * 7.97259e-13)

At the start of the cruise the laboratory test-derived conductivity calibration coefficient 
(0.001000215) was applied to the raw data. For cast 12943 the bottle salinities were 
compared with the CTD upcast salinities and there was generally an offset of approximately -
0.48 psu. A new conductivity ratio was re-calculated (cratio) from the CTD pressure, 
temperature and conductivity compared to the "true" salinity of the bottles. The new 
coefficient is the product of the new ratio and the original coefficient. Final corrections to the 
salinity were made by applying a constant offset to salinity on a cast by cast basis (see 
below). At Station 12970 the conductivity sensor was damaged by a loose Niskin bottle and a 
new sensor fitted. The same procedure was used to derive a new conductivity calibration from 
bottle salinities.

So for stations 12932 to 12970 Conductivity = Craw * 0.000989924

for stations 12971 to 13018 Conductivity = Craw * 0.000988156


Oxygen current (oxyc) was initially calibrated as follows:

oxyc = (ocraw * 0.001) * 1.35

and 

oxyfrac = oxyc * exp ((-0.035 * ctemp) + (0.000145 * press))

where ctemp = (temp * 0.4) + ((1- 0.4) * oxyt)

Most of these parameters were rederived in later calibration ( 3.1.4).

The altimeter, used primarily to detect the height of the CTD off the bottom when it was 
within 200m of the bottom of the cast, was calibrated as follows:

altimetry = 0.20299 + (altraw * 0.0051479) + (altraw2 * -5.861688e-8)

Two transmissometers were used; SeaTech (trans) and Chelsea Instruments No 003 (trans2). 
The transmittance was first calibrated using the polynomial expressions:

trans = -0.001719631 + (tnraw * 0.001219711) + (tnraw2 * 3.438596e-10)

trans2 = 0.00181789 + (tn2raw * 0.0012193) + (tn2raw2 * 6.05678e-10)

The transmittance was then further corrected for the ageing of the light source by comparing 
the clean air deck volts at the start of Di223 (e.g. 3.997 for SeaTech No 003) with the 
manufacturers calibration (e.g. for SeaTech No 003, water calibration of 1.002 when the air 
value was 4.28V). 

trans => trans * 1.002 * 4.28 / 3.997

trans2 => trans2 * 1 * 4.66 / 4.732


The fluorescence was initially logged as uncalibrated voltage using the following equation to 
convert from the raw units:

fvolts = -0.001719631 + (fraw * 0.001219711) + (fraw2 * 3.438596e-10)

The nitrate sensor logged three channels of light attenuation at different wavelengths. The 
attenuation was initially logged as uncalibrated voltage using the following equation to convert 
each channel from the raw units:

avolts = 0.00181789 + (araw * 0.00121934) + (araw2 * 6.05678e-10)

(N.P.Holliday, R.T.Pollard)


Bottle Firing Depths and Sample Files

The CTD deck unit logged the time and confirmation code of each Niskin bottle firing, and the 
data were transferred to the Level A and subsequently into PSTAR files (datapup). On some 
occasions the firing times were not logged by the Level A, so the times were inferred from 
periods of constant pressure data in the upcast CTD file. This occurred at 3 stations when the 
Level A was not reset prior to the cast, and if the bottle data cable connecting the deck unit to 
Level A became loose.

The firing times were merged with the winch cableout data for each station, then the 10-
second averaged upcast and 1-second downcast CTD data. Down cast data were matched 
(pbotle) with upcast data by potential temperature, and used only to calibrate the oxygen data 
( 3.1.4).

The firing data and merged CTD data were pasted into sample files along with other bottle 
sample data such as salinity, oxygen, nutrients and CFCs, and the reversing thermometer and 
pressure meter readings. Each sample file contained 24 datacycles, one per bottle on the 
rosette. The difference between the bottle salinity and the downcast CTD salinity was used to 
check for possible misfires, then to calibrate the CTD salinity data (see below). No problems 
with double firings or incorrect firing depths were encountered. Occasionally the CTD firing 
control panel returned a "bottle already fired" code and the operator fired another bottle at the 
same depth. The improved reliability of the bottle firings from the new pylon is much 
appreciated. 
(N.P.Holliday)


Salinity Calibration

After the conductivity coefficient was calculated from bottle salinities early in the cruise, a 
mean offset was calculated for each cast. Values with large differences (leaky bottles, bad 
samples, and samples drawn in high salinity gradients) were excluded from the mean. The 
mean offset was also calculated for samples from >1000 dbar where there is less spread in 
salinity values. The two means determined the offset applied to each cast to match the CTD 
salinities to the bottle salinities. Table 4 contains all the calculated mean offsets, their standard 
deviation, and the offset applied. The offset drifts in a minor way throughout the cruise 
(Fig.4).

After calibration the residuals between the CTD upcast data and the bottle data were 
recalculated (Fig.5). The final mean of calibrated residuals across all D223 CTD casts was 
0.0278  0.3395 for all data points, but 0.0009  0.0029 excluding offsets >0.02 and < 
-0.02.
(N.P.Holliday)

A listing of the calibration file deepctd.cal is given in Table 11.


3.1.4 Oxygen calibration

There are several stages to the calibration of the oxygen current measurements from the CTD 
to give oxygen concentrations in mmol/l. Firstly a least squares fit is performed between the 
CTD oxygen current values and the bottle sample oxygens on a selection of the casts to find 
the best parameters with which to make an initial calibration. The best parameters are chosen 
and applied to the oxygen current values. The second stage of the process is to use a cubic 
spline fitting routine to reduce further the differences between the bottle sample oxygen 
concentrations and the calibrated CTD oxygen values. This stage may need several iterations 
to find suitable values. The final stage is to replace the surface CTD oxygen values with 
interpolated bottle sample concentrations as the CTD values are particularly unreliable near 
the surface.


Derivation of Calibration Parameters

The relationship between oxygen concentration and the parameters measured with the CTD 
is:

oxygen = oxycurr * rho * exp[alpha * T + beta * P] + oxysat(T, S)
 
where oxygen is the oxygen concentration (in mmol/l ), oxycurr is the CTD oxygen current 
measurement (mamps), T is the temperature (C), P is the pressure (dbar) and oxysat is the 
saturation oxygen concentration (in mmol/l ) which is itself a function of temperature and 
salinity. Alpha, beta and rho are the fitting parameters.

Alpha, beta and rho need to be determined from a comparison of the oxygen bottle sample 
concentrations and the oxygen current measurements as a function of temperature, pressure 
and salinity. As the pressure and the temperature are both often monotonic with depth to 
about 2000 m the best fits are obtained with deep casts as these profiles have often reached 
depths where the temperature is approximately constant whilst the pressure still increases, 
allowing the effect of each to be determined. The procedure followed to find the 'constants' is 
as follows.

The script oxyexec reads values of pressure, temperature, salinity, oxygen current and bottle 
oxygen from the sample file. One complication that should be noted is that the CTD 
parameters measured on the down cast are compared with the bottle values measured on the 
upcast. The reason for this is that the upcast values for oxygen current are unreliable as the 
firing of the bottles on the upcast disrupts the oxygen measurement which takes a while to 
recover (B King, D189). If the CTD profile plots are examined it will be seen that the oxygen 
values on the up and on the down cast are usually offset by quite large values. The sample file 
therefore contains two pressure measurements, dpress and upress. dpress is an estimate of the 
pressure measured on the downcast where the salinity and temperature best match the values 
measured on the upcast when the bottle was fired. These two pressures are usually similar, 
except that dpress may be inaccurate in the surface layer where salinity and temperature are 
well mixed. dpress is the appropriate pressure value to use in oxyexec.

Oxyexec runs the program oxyca3 and requires initial estimates of alpha, beta, rho and two 
parameters 'frac' and 'offset'. frac is used when a lagged temperature is constructed from 
temperature and oxygen temperature (not measured on D223) and offset is a bias in the 
oxygen current. These were set to 1 (indicating that temperature alone is used instead of a 
lagged temperature) and 0 (no oxygen current offset). oxyca3 allows some or all of the 
parameters to be excluded from the fit. The script oxyexec was edited to initially fit all of 
alpha, beta and rho. Oxyexec prints a table of the input parameters and the fitted oxygen, a list 
of differences is plotted which is examined to see if any erroneous values are present. If errors 
(usually in the bottle sample value or near the surface) are found the exec is re-run excluding 
the bad values to get a better fit. The excluded values were checked with the oxygen sample 
analysis logs as there was sometimes a mistake in the sample value which can be corrected. If 
there is no mistake the sample can be flagged as suspect if appropriate. Oxyexec gives the 
option to calibrate the files, this was not be done at this stage.
Once a reasonable number of deep casts have been made, the values of alpha and beta can be 
chosen. Fig.6 shows how alpha and beta vary with depth for casts at the beginning of Leg 2. 
 
As Leg 1 had few really deep casts the values of alpha and beta had been initially estimated to 
be -0.0001623 and 0.01659 respectively. These can be seen from the graphs to be similar to 
the Leg 2 values for depths around 2000 dbar. As the parameters are better defined for deep 
casts the values for Leg 2 were taken to be -0.0001402 and 0.02413 (averages for the deep 
casts 12996, 13002, 13004 and 13005). The calibration for Leg 1 was not recalculated.

With the parameters alpha and beta now fixed, oxyexec was edited to only fit rho, with alpha 
and beta fixed. A different value of rho is now found for each cast and the option to calibrate 
the data (both the CTD master file and the sample file, using the program oxygn3 within 
oxyexec) was taken.

The program oxspln was then used to fit cubic splines to the differences between the bottle 
and the CTD oxygens in the sample file. Oxygen samples can be excluded from the fit as 
necessary. Knot points are selected to give a smooth error curve that best corrects the CTD 
oxygen values towards the bottle values. These errors are used to correct the CTD file oxygen 
values. As the CTD oxygens are not reliable near the surface they are next replaced with 
interpolated bottle data. The file is first averaged to 9 second values using pfiltr. The bottle 
oxygen values are interpolated onto the CTD file and are used to overwrite the CTD oxygen 
values in the surface layer.
(M.-M.Lee, E.C.Kent)


3.1.5 Reversing Thermometers and Pressure Meters

SIS digital reversing thermometers and pressure meters were used on all CTD casts. 
Throughout the cruise the meters on the CTD multisampler rosette were T714 and P6132 on 
Bottle 1, and T743, T746 and P6243 on Bottle 4. Meters T401 and P6075 were kept as spare 
or for deeper stations using more bottles on the rosette. Laboratory calibrations were applied 
to all the meters (in Excel spreadsheets), and the resulting values used primarily as a check on 
the consistency and quality of the CTD data (ftp from Mac hard disk, ppaste into sample 
files). Experience shows that the CTD data is more stable than the reversing thermometers and 
pressure meters, so they were not used to correct the CTD data. However, the differences 
were used to check the calibration of the CTD thermometer after station 12971. The unit 
received a knock from a loose Niskin bottle and the conductivity sensor was damaged and 
replaced. The offsets of CTD temperature and pressure from the reversing meters confirmed 
that there was no change in the calibration of the CTD temperature and pressure sensors. 
Table 5 shows the mean and standard deviations of the differences between the CTD and 
meter data.
(N.P.Holliday)


3.2 Chemical tracers studies 

Chemical tracer studies were primarily focused on the measurement of CFC- 11, CFC-12, 
CFC-113 and carbon tetrachloride in order to span rates of formation and spreading of the 
dominant water masses of the North Atlantic over the last 70 years. Water masses which were 
particularly targeted were the bottom waters of southern ocean origin, the northern overflow 
waters, Labrador Sea Water and the recently ventilated mixed layer water. Of particularly 
interest was the movement of Labrador Sea Water across the North Atlantic and its possible 
recirculation in the Rockall Trough. CFCs were measured at 34 of the closely spaced stations 
from the UK to Iceland and all of those along the section into Greenland. In addition samples 
were analysed from all but 5 of the stations during the SeaSoar survey.

	
3.2.1 CFC Sample Collection

All samples were collected from depth using the SOC 10 litre Niskin bottles, restricted for 
CFC work. All 'O' rings, seals and taps were removed from the bottles, at the beginning of the 
cruise and replaced with ones washed in deacon solution and propan-2-ol then baked in a 
vacuum oven for 24 hours. Reassembling of the bottles was carried out at the beginning of the 
cruise and the bottles immediately positioned on the rosette to minimise contamination. CFC-
113 contamination was suspected from about station 13011, prompting the replacement of all 
the bottle taps and later of a couple of the bottles. However this failed to resolve the problem, 
indicating another source for the contamination. All bottles in use remained outside on deck 
throughout the cruise, those not in use were stored in aluminium boxes inside the hanger where 
there was a free flow of air to minimise contamination. Samples for analysis were drawn first 
from the Niskin bottles directly into 100 ml gas tight syringes and these were stored under 
clean sea water.


3.2.2 CFC Analysis

Chlorofluorocarbons CFC-11, CFC-12 and CFC-113 were measured at a total of 39 stations 
by DSW, SMB, CRH and CD during the first leg and a total of 23 station by SMB, CRH and 
CD on the second leg. The analytical measuring technique was as described in Boswell and 
Smythe-Wright (1996), with a modified pressure standard injection system enabling the 
system to be pressurises to 4 bar. This allowed for a maximum sample injection of 16 large 
loop volumes totalling 80 ml. Duplicate samples and air samples were run as often as 
analytical time allowed. Air samples were drawn in a clean 100 ml syringe at a windward 
location on the ship. All CFC analyses were calibrated using calibration curves constructed 
from a gas standard calibrated by NOAA CMDL. This standard had previously been cross 
calibrated for CFC-11 and CFC-12 to the SIO 1993 scale. At the commencement of the cruise 
some CFC-11 contamination was found in the large gas standard loop. Despite, cleaning the 
contamination persisted and the problem was alleviated by connecting the standard line from 
the GC/MS system used for the halocarbon analysis to the ECD system. About half way 
through the first leg the system was changed to the original configuration and standard 
injections from the small gas standard loop, which was found to be clean, used for the 
remainder of the cruise. Due to operator error at station 12977 water inadvertently entered the 
GC system rendering the A channel of the dual detector system non-operational. Both the A 
and B systems were found to have blocked precolumns. These were cleaned and analysis 
continued on the B channel. After some days the contamination on the A system ECD cleared 
and it was possible to run the A system to a limited extent. After the mid cruise port call the 
A channel precolumn was changed and both detectors used until station 13001 when channel 
A developed severe baseline noise which rendered accurate quantification impossible. At this 
point analysis was switched entirely to the B channel. Shortly after the start of the second leg 
the system developed severe contamination in the region of the CFC-12 peak. This continued 
throughout the Greenland section and intermittently for the rest of the cruise. It was 
eventually traced back to the vacuum oven, probably due to traces of oil mist from the 
vacuum pump. Despite thorough cleaning of the oven and all glassware contained therein, the 
problem reappeared on several occasions, requiring a bake out of the CFC analytical 
equipment. CFC-113 contamination from station 13011 onwards did not appear to be derived 
from the sampling bottles and may be related to the CFC-12 problem. Due to early suspicion 
falling on the drying material used (magnesium perchlorate), potassium carbonate was used in 
the drying tubes from station 13006 onwards. This appeared to be a superior desiccant but 
needs oven temperatures much higher than are compatible with some system components, 
possibly requiring the use of two ovens in the future. After station 12986, a new standards 
generator was tried, in order to calibrate for other compounds. However, this produced very 
high levels of carbon tetrachloride which swamped the system and led to problematic results 
for a number of stations into the 2nd leg. 


3.2.3 Halocarbon Studies

The objective of the halocarbon analysis was to establish the ocean as a net source or sink of a 
number of halogenated compounds which are known to be produced by marine algae and are 
important in environment/climate change issues. The compounds involved are diverse, 
however as an initial study, the cruise work focused on the development of gas 
chromatography/ mass spectrometry techniques for the analysis of methyl chloride, methyl 
bromide, methyl iodide and methylene chloride at sea water concentrations. Samples were also 
analysed for CFCs to evaluate the GC/ECD system. 


3.2.4 Halocarbon Sample Collection

Samples were collected directly from the Niskin bottles into 100 ml gas tight syringes, 
immediately following the CFC samples. Here possible, duplicate samples were taken to 
increase sample volume, and an extra bottle fired at the surface to permit a five- syringe 
injection to be made. Work was concentrated on the top six depths (down to 200 m) but 6 
stations were analysed to full depth. In all, 211 samples were analysed from 24 stations.


3.2.5 Halocarbon Analysis

Analysis was carried out using a modified version of the normal CFC equipment. A single 
channel system with the two trapping valves mounted externally to the GC oven. The column 
itself provided the link between sample board and GC. Samples were stripped and trapped as 
normal, but using a 60 ml stripping chamber and 8 minutes stripping time. On completion of 
the first of a pair of duplicates the trap was closed but kept cold and the second sample 
loaded and stripped into the same trap. For injection into the mass spectrometer, a loop of the 
column was placed into a Dewar of liquid nitrogen and the analytes desorbed from the trap, 
thus refocusing them into a tight plug. Final injection was achieved by removing the column 
from the Dewar and wiping it between finger and thumb, the low thermal mass of the column 
requiring only minimal warming. Mass spectral analysis was performed using selective ion 
monitoring, whereby only ions specific to the compounds of interest were measured. This 
permits discrimination of poorly resolved compound while providing enhanced sensitivity 
over full scan mode due to the longer dwell time on ions of interest. The experimental nature 
of this set-up means that the system was not optimised for ultimate sensitivity, especially in 
terms of the column flow rate into the mass spectrometer which was much higher than 
recommended. However initial analysis of results suggest detection limits of 0.1 pmol/kg for 
CFC-11 and 0.3 pmol/kg for CFC-12. Calibration of other compounds was hampered by 
problems with the standards generator (see above), but will be addressed back at SOC.

(D.Smythe-Wright, S.M.Boswell, C.R.Harris)


3.3 Salinity Bottle Samples

Salinity samples were take from each bottle of each cast and determined using a Guildline 
Autosal salinometer. The values were entered into spreadsheets and PSTAR bottle files (q.v. 
2.5.1 Thermosalinograph Temperature and Salinity and 3.1.3 CTD Data Processing and 
Calibration). At the beginning of Leg 1 there was a problem with the stability of the 
temperature in the Controlled Temperature Laboratory. The salinity differences for the 
standards are shown in Table 15 and Fig.8.


3.4 Oxygen Bottle Samples

Oxygen samples were drawn from every bottle following the collection of samples for CFC 
analysis. Duplicate samples were taken on each cast, usually from the first two bottles. 
Samples were drawn into clear, wide necked calibrated glass bottles and fixed on deck with 
reagents dispensed using Anachem bottle top dispensers. A test station was used to check on 
the oxygen bottle calibrations and as an opportunity to train a number of people to take the 
samples. The samples were shaken on deck and again in the laboratory 1/2 hour after 
collection, when the bottles were checked for the tightness of the stoppers and presence of 
bubbles. The samples were then stored under water until analysis. 

Bottle temperatures were taken, following sampling for oxygen, using a hand held electronic 
thermometer probe. The temperatures were used to calculate any temperature-dependent 
changes in the sample bottle volumes. The probe used was damaged on station 12987 and had 
to be repaired. 

Samples were analysed in the constant temperature laboratory, starting two hours after 
sample collection, following the Winkler whole bottle titration with an amperometric method 
of endpoint detection, as described by Culberson and Huang (1987). The equipment used was 
supplied by Metrohm and included the Titrino unit and control pad, exchange unit with 5 ml 
burette (unit 3) to dispense the thiosulphate in increments of 1 _l, with an electrode for 
amperometric end point detection. 

The mean difference for the duplicate pairs sampled on each station was 0.799 _mol/l (0.25% 
full scale precision). The data quality may be affected by the amount of time that the Niskin 
bottles were open and warming up on deck prior to sampling. The rate limiting step in the 
sampling procedure was the CFC sampling where up to five replicates were taken on some 
occasions. 

The thiosulphate normality was checked on each run and recalculated every time the reservoir 
was topped up, and every 3 days, against potassium iodate. The exact weight of this standard, 
the calibration of the 10 ml exchange unit (number 1a) driven by a Metrohm Dosimat and the 
1L glass volumetric flask used to dispense and prepare the standard, were accounted for in the 
Mac worksheet used to calculate the oxygen values. This standardisation was also repeated 
when fresh iodate standard was prepared which was on five occasions during the cruise. 

Very variable standardisation on first batch of standard was probably related to the variable 
laboratory temperature at the beginning of Leg 1 and the introduction of bubbles.

The introduction of oxygen with the reagents and impurities in the manganese chloride were 
corrected for by blank measurements made on each station, as described in the WOCE Manual 
of Operations and Methods (Culberson, 1991). The iodate standards were added to the excess 
reagents following the blank measurements as there was some question about the order of 
addition of the chemicals and standard material (the differences between adding iodate before 
or after the acid, iodide and manganous chloride appear to be related to reagent batch and 
adding the standard toe the excess reagent removes these differences). 

The thiosulphate normality was checked against a commercially prepared standard (Sagami 
Chemical Company, Japan). It was dispensed using the Eppendorf 1 ml pipette and compared 
against the in house standard dispensed in the same way. On each occasion the thiosulphate 
normality was equivalent using the iodate working standard and that supplied by Sagami. 

Data comparisons were made against CONVEX data. Six equivalent stations were compared 
by overlaying profiles:- The bottom water oxygen values differed by  4 _mol/l between 
station 12994 on this cruise and 62038 for the CONVEX data otherwise the stations showed 
good agreement.

References:
Culberson, C.H. and S.Huang, 1987. Automated amperometric oxygen titration. Deep Sea 
Research, 34, 875-880.
Culberson, C.H. 1991. 15 pp in the WOCE Operations Manual (WHP Operations and 
Methods) WHPO 91/1, Woods Hole. 
(S.E.Holley, A.Mustard)


3.5 Nutrient Bottle Samples

A total of 84 casts were sampled for nutrients during the two Legs of this cruise. Depths 
ranged from 500m to over 3000m. Duplicate samples for nutrient measurements were 
collected following CFC and oxygen samples from each Niskin bottle. Water was collected in 
clean plastic diluvial containers that had been rinsed three times. One duplicate was stored in 
the refrigerator and analysed within 12 hours, whilst the other duplicate was stored at 5C in 
the cold room. Water collected from the Niskins on each CTD cast was poured into individual 
8 ml sample cups and mounted on the sampler turntable and analysed in sequence, with the 
results recorded by chart recorder and by computer run peak height analysis software.
 Concentrations of nitrate/nitrite, silicate and phosphate were determined by segmented flow 
analysis on a Chemlab Autoanalyser system with autosampling. Each sample was analysed in 
duplicate to ensure accuracy and increase precision. Several quality control samples were also 
analysed on each run to provide a measure of drift which is inherent in this type of analysis. 
The quality control samples were made up from standard solutions supplied by OSI in 
addition to a deep water sample collected from ca. 3000m. The OSI standards were made up 
and stored in calibrated plastic volumetric flasks. The deep water QC samples were decanted 
into clean rinsed plastic diluvial containers and stored in the refrigerator until required.

Primary standards used for the calibration of the autoanalyser were made up in calibrated 500 
ml glass volumetric flasks (except for the silicate standard, which was made up in a calibrated 
polyethylene volumetric flask) in fresh water approximately every four weeks and stored in 
the refrigerator to reduce deterioration of the solutions. These primary standards were made 
up from pre-weighed salts that had been accurately weighed prior to the start of the cruise. 
Mixed working standards were made up approximately once per day in 100 ml calibrated 
polyethylene volumetric flasks in artificial seawater (@ 40g/l NaCl) . The concentrations of 
the working standards used for discrete nutrient analysis were as follows:

Silicate 40 mol l-1, 30 mol l-1, 20 mol l-1, 10 mol l-1
Nitrate 40 mol l-1, 30 mol l-1, 20 mol l-1, 10 mol l-1
Phosphate 2.0 mol l-1, 1.50 mol l-1, 1.00 mol l-1, 0.50 mol l-1

 The autoanalyser, although reliable, required periodic maintenance throughout the course of 
the cruise. The tubing on the peristaltic pump was replaced at approximately two week 
intervals to maintain maximum sensitivity in the analysis. And a complete re-tubing of the 
analyser was performed at the end of the Leg 1 of the cruise. At this time the system was 
flushed with DECON and distilled water before further samples were analysed. Prior to each 
analysis, a set of standard solutions was run to check that the system was operating correctly. 
Reagents for each of the nutrients analysed were made up as and when required from pre-
weighed salts.

A total of 6214 analyses were carried out over the duration of the two legs including 
standards, drifts and quality control samples. Results indicated reduced nutrient 
concentrations in the surface waters at the start of the Leg 1 with concentrations of all three 
nutrients measured increasing over the course of the Leg 2. Deep water nutrient concentrations 
whilst higher than at the surface showed significant rises as the course of the ship turned 
south.


Problems with the Autoanalyser.

A number of problems were encountered during the course of the two legs of this cruise with 
respect to re-tubing of the discrete autoanalyser system. Firstly, when the system is retubed 
the nitrate channel exhibited the peculiar action of sucking fluid back up the waste tube 
through the flow cell. This occurred at the same time as an increase in pressure in the system 
so much so that joints in the system between tubes burst apart. The problem eventually 
disappeared after continuous running of nitrate reagents, but required several days before 
becoming fully functional. This was not too great a problem during this cruise as the rate of 
sample acquisition was not too great, but if the workload had become much heavier then a 
serious backlog of samples would have built up very rapidly. On further investigation it 
appeared that when the cadmium column was replenished with extra cadmium particles, a fine 
dust accumulated in the column which caused a reduction in flow rate though the column to 
such an extent that the pressure in the column increased. To remedy this, a syringe filled with 
water was employed to clear away the dust from within the column. This was probably a 
result of the narrow bore of the cadmium column housing.

(M.S.Finch)


3.6 Nitrate Sensor

A prototype ultra violet nitrate sensor was mounted on the CTD rig in an attempt to 
determine the validity of using this type of sensor at sea for the continuous measurement of 
nitrate. During the Leg 1 it was noticed that the 300 nm channel was producing a voltage 
greater than 5.5V which was interfering with the A/D CTD system. This required the removal 
of the sensor from the CTD rig until the voltage could be brought down to below 5V. After 
consultation with colleagues at SOC, the sensor was modified to halve the voltage output on 
the 300 nm channel and the sensor was remounted on the CTD rig. This modification was 
carried out whilst on board ship by the addition of two 10K resistors. For further information 
see the section on CTD operation. Results from the Leg 2, whilst still to be analysed in detail, 
are encouraging. Some casts show hysteresis, particularly on the 220 nm channel, but not on 
the 240 nm channel. The results produced from the chemical analysis of nitrate from the CTD 
casts will be used to calibrate the results from the UV nitrate sensor.

(M.S.Finch)


3.7 Oxygen Isotope Samples

The purpose of the 18O sampling is its inclusion in a study of the contribution the regional sea 
make in the formation of North Atlantic Deep Water. 18O acts as a tracer much like salinity, 
the 18O distribution being primarily determined by the precipitation - evaporation regime. 
However unlike salinity 18O is left effectively unchanged by sea - ice processes giving it an 
extra degree of freedom where sea - ice processes occur.

Samples were taken from CTD casts at stations indicated in the cast list for analysis back at 
the University of East Anglia. The sea water is analysed using a modification of the standard 
CO2 - H2O 18O isotope equilibration technique (Dennis et al. 1995). The samples were 
collected in new 150 ml Winchester bottles leaving head space for expansion, the small amount 
of CO2 in the head space not affecting the 18O value. The bottles being new only required one 
rinse. The bottles were then sealed with rubber lined metal caps and further sealed, within 24 
hours, with Nesco film in order to prevent evaporation and consequent change in 18O value.

Reference
Dennis P. F, R. D. Frew and A. Etchells, A rapid high precision system for O-18 
determination of natural waters. Submitted to J. Atmos. Ocean Tech. 1995.

(T.A.Winters)


3.8 Plankton Speciation and Pigment analysis

Water samples were collected between 0-200 m for plankton speciation and plant pigment 
analysis in order to interpret the halocarbon data in relation to prevailing biological activity. 
Forty three stations were sampled. Samples for plankton identification were collected from 2 
depths, usually surface and 25 or 50m. For each of the depths two 100 ml bottles, one 
containing 1 ml lugols solution and the other containing 2 ml 40% formalin were filled with 
water. 180 samples were taken overall. At the top 6 depths between 2 and 4 l of sea water 
were collected and immediately filtered through 25 mm GFF filters. The filters were 
subsequently placed in cryotubes and stored in liquid nitrogen. 258 samples were filtered. In 
addition some assessment of the less than 2 mm diameter cells to total chlorophyll was made 
at the same depths as the plankton speciation samples by filtering 100 ml water through 2 mm 
filters, passing the filtrate through 25 mm GFF filters and measuring the chlorophyll by 
normal acetone extraction procedure. This could then be compared with the conventional 
chlorophyll samples filtered through 25 mm GFF filters. Approximately 90 <2 mm samples 
were filtered.
(D.Smythe-Wright, S.M.Boswell, C.Deubert)


3.9 Chlorophyll Samples and Fluorescence Calibration

3.9.1 Chlorophyll Determinations

Chlorophyll samples were taken to calibrate the CTD fluorometer, the TSG fluorometer and 
consequently the SeaSoar. CTD chlorophyll sampling concentrated on the mixed layer with 
the top 2, 4 or 5 Niskin bottles being sampled depending on whether HPLC samples were 
being taken. Chlorophyll was the last sample that was taken from the bottle rosette. Also 
about every 5 stations water from below the mixed layer was sampled. Alberto Naveira 
Garabato advised that calibration was possible with just 2 to 3 mixed layer samples, even in 
daylight, because of the low chlorophyll concentrations at these latitudes during the cruise. 
Underway samples were taken hourly when the SeaSoar was deployed, and samples were 
drawn from the non-toxic hose in the hanger which is the same non-toxic supply as the TSG 
fluorometer.

Samples were collected in 500 ml plastic flasks which were rinsed in the sample prior to being 
filled. Immediately three 100 ml aliquots measured out in a cut off volumetric flask were 
filtered through 3 Whatman GF/F 25 mm filters at low pressure (<6 mm Hg). Filtering was 
done in reduced light, with the bottle annexe lights off and a black plastic bin liner covering the 
filters. Once the method produced sensible precise results this was reduced to two filters per 
sample. The papers were placed in glass vials and immediately in the dark at -20C.

20 ml of 90% acetone was added to batches of 50 samples daily from an Anachem 25 ml 
adjustable autodispenser, to extract the chlorophyll, and they were placed in the freezer for 22 
to 24 hours. Smaller batches of ten samples were then warmed to room temperature in a dark 
water bath before the fluorescence was measured in a Turner Designs Fluorometer (model 10-
000R, serial no. 00859). Then 4 drops of 10% hydrochloric acid were added to the sample and 
the fluorescence remeasured.

Chlorophyll solutions (sigma chlorophyll) covering the expected range of the samples were 
used for calibration standards and were made up and measured along with blanks for each 50 
samples. Two primary standards were used which were stored in the freezer and used to make 
up the standards. The chlorophyll concentration of these was calculated from the absorbance 
measured before and after acid at 665 and 750 nm in Pye Unicam SP6-500 spectrophotometer.

Chlorophyll and phaeopigment concentrations were calculated using the equations from the 
JGOFS protocols (1994) in Microsoft Excel and the resulting values were imported into 
PSTAR in text files.

Equations
standard concentration:
Chlorophyll a (mg m-3) 	=	26.7(665b-665a)v/l		
Phaeopigments (mg m-3)	=	26.7((1.7_665a)-665b)v/l	
where:	665b =3D Absorbance at 665 nm before acidification.
	665a =3D Absorbance at 665 nm after acidification.
	v = Volume of extract (ml)
	l = path length of cuvette (cm)

Sample concentrations:
Chlorophyll a (mg m-3)	= FD_(Fm/(Fm-1))_(Fb-Fa)_(v/V)
Phaeopigments (mg m-3)	= FD_(Fm/(Fm-1))_((Fm_Fb)-Fa)_(v/V)
where:	 FD = Chlorophyll Standard concentration / Chlorophyll standard
Fluorescence before acidification.
	Fb, Fa = Fluorescence value before and after acidification of sample.
	Fm = Fb/Fa of chl a standard solution.
	v = volume of 90% acetone used in extraction(ml).
	V = Volume of seawater filtered (ml).


During the cruise 1870 discrete chlorophyll samples were taken and analysed. The range of 
concentrations varied in the mixed layer from 0.2 mg m-3 to 0.7 mg m-3, and in the coastal 
water close to Iceland were as high as 1.5 mg m-3. The precision of the method was estimated 
by comparing the standard deviations of the duplicates of the underway chlorophyll 
measurements. This resulted in a standard deviation of 0.0053 . The main areas which were 
identified as the sources of inaccuracies were filtering leakages and imprecise measurements of 
sample volume in the cut off volumetric flask. The Turner fluorometer was also effected by 
the motion of the ship, and the normal readable accuracy of three significant figures was 
reduced because the needle swung with the ship.

References:
Holm-Hansen, O., and Riemann, B., (1978) Chlorophyll a determination: improvements in 
methodology. Oikos 30: 438-447.
JGOFS Protocols Draft March 1994.
(A.T.Mustard)


3.9.2 Fluorescence Calibration

A Chelsea Instruments Aquatracka III fluorometer mounted horizontally was included in the 
CTD package during Vivaldi 96. Conversion of continuous fluorometric measurements made 
with this device to profiles of chlorophyll a concentration could be accomplished by reference 
to bottle samples taken at various depths over each single cast.

Previously to the calibration, a constant offset fluorescence value of 0.98 (arbitrary 
fluorescence units) was substracted to the whole data set in order to improve the consistency 
of the derived deep chlorophyll a concentration data, optimising convergence of records from 
different stations at depth. Calculation of the fluorescence yield R (the ratio of fluorescence to 
chlorophyll a concentration) at every available sample point followed. As this parameter is 
highly variable, depending on a wide range of factors such as ambient light field, 
phytoplankton species composition and physiological state or nutrient supply, the change of 
R with depth was initially investigated.

Little dependence of fluorescence yield R on depth was appreciated within the well-mixed 
layer that dominated the top tens of meters over the whole Vivaldi 96 survey, small 
fluctuations (of magnitude ~5%) around a mean local value being most probably due to 
random sampling errors or natural patchiness. The larger (by up to an order of magnitude), 
apparently chaotic fluctuations in R encountered deeper down the water column are thought 
to be a fictitious effect introduced by the calculation of R as the ratio of two numbers close to 
zero. Given the reduced fluorescence readings at these depths, sensitivity of derived deep 
chlorophyll concentrations to the choice of R proved insignificant.

With this background, the strategy of estimating a single value of R for each fluorescence 
profile was adopted. By means of that simplification, the original shapes of the fluorescence 
profiles were rigorously preserved and derivation of chlorophyll a concentrations over the 
whole water column for those casts in which only a single bottle sample had been taken was 
made possible.

Only in certain strongly-illuminated locations had this approach to be modified. The reason 
for this was the light-dependency of R, usually referred to as light quenching. Namely, the 
relationship between fluorescence yield and ambient irradiance is that of a negative correlation, 
a consequence of the changing photoadaptive state of phytoplankton. Though quenching 
effects encountered during Vivaldi 96 were generally small in comparison with other often 
observed oceanic scenarios, they were by no means negligible. 

Given that no irradiance meter had been mounted in the CTD frame that could assist the 
description of variations in R as a function of light intensity, several bottle samples were 
needed to infer those variations along the illuminated sector of the water column. Wherever the 
required samples were made available, linear interpolation (pintrp) between sample points 
provided a depth-dependent definition of R. When the number of bottle samples was 
insufficient, quenched data were edited out (peditb).

At this stage, having defined R over the widest range as it was judged possible, a trivial 
calculation (parith) of chlorophyll a concentration as the ratio of in situ fluorescence and the 
corresponding fluorescence yield remained.

The original fluorescence profiles were somewhat spiky, specially in gradient zones and below 
the mixed layer, and these features were obviously still present in chlorophyll a concentration 
profiles after calibration. Only the most prominent spikes were removed (peditb). Caution 
should be taken when considering fine structure in such profiles.
Errors introduced by the calibration are difficult to estimate and, given the natural patchiness 
of phytoplankton, may vary considerably with the number of bottle samples available per 
cast. Based on fluctuations in R as calculated from the different samples in a multiple sample 
cast, typical figures of 0.01 and 0.04 mg m-3 may be quoted for the expected error in the 
(mean mixed layer) calibrated chlorophyll a concentration of a three sample cast and a one 
sample cast, respectively. The concentrations so obtained were gridded and contoured for the 
three CTD sections in the Leg 1 and obvious correlation with oxygen concentration and 
salinity structures could be visually appreciated. Accordingly, calibrated chlorophyll data 
from the CTD fluorometer were found to be remarkably consistent with those recorded by a 
similar instrument mounted on the towed undulating fish Sea Soar, measurements from which 
underwent a completely independent calibration treatment.

A sampling strategy of 2/3 bottle samples per night-time cast and 3 samples per day-time 
cast, with emphasis in the top (probably quenched) 20 m, is recommended for future cruises 
where similar well-mixed, relatively weakly quenched water columns are encountered.

(A.C.Naveira Garabato)


3.10 Lowered Acoustic Doppler Current Profiler (LADCP)

The RDI 150 kHz ADCP consists of a 33 inch pressure case rated to 6000 metres with 4 
transducers at one end in a convex arrangement and the beams diverging at 30 degrees from the 
vertical. At the opposite end to the transducers are two connectors one of which enables 
downloading of data and the other which connects it to another pressure case containing the 
power supply pack. This arrangement allowed the ADCP to be mounted centrally and 
vertically on the CTD frame whilst the battery pack was mounted horizontally near its base. 
A fly lead was left attached permanently to the unit, the other end of which was lashed to one 
of the CTD's vertical supports, this enabled a comms lead to be readily connected pre and 
post deployment.

Communications: The communications lead (which also allows external power to be supplied 
to the ADCP) was sufficiently long to route it through to the port side of the deck lab where 
it was connected to a dedicated PC and external power supply. The latter was set at 40+ volts 
and was left on whilst the ADCP was on deck. 10-15 minutes prior to deployment the 
external power supply was shut off, the instrument checked and the configuration file sent to 
the ADCP as described in the manual instructions. The ADCP end of the communications 
lead was fed back into the bottle annex to keep it from the elements. The free end of the fly 
lead was greased and the end cap refitted, this was then taped to the frame for security. 

Post deployment: When the CTD/LADCP was brought inboard, the fly-lead connector was 
dried and the comms lead fed over the top of the CTD frame and connected to it. This 
stopped undue bending of the cable and kept it clear of the water bottles, aiding sampling. 
External power was applied again and the cast data downloaded as per the manual. The 
processing is accomplished using software developed by Eric Firing (Univ. of Hawaii) after 
transferring the data to a UNIX workstation.

Battery power was supplied to the ADCP in the form of 36 volts from 24 _ 1.5 volt alkaline 
cells. Four of these packs were available for the cruise, as the ADCP will function at a 
minimum of 20 volts this was deemed an adequate stock for the duration. However the ADCP 
failed to log during the downcast of CTD 12964 at 900 metres, the battery voltage was 
measured when the unit was on deck and found to be 32.2 volts (the ADCP was using a 
bottom tracking configuration). No errors were reported by the unit and so it was deployed 
again. At 890 metres, during the upcast of CTD 12972, the unit stopped recording again in a 
bottom tracking mode. The voltage was 31.6 volts at the surface. The next cast reported an 
error code 00000080 and during the following CTD, 12974, the ADCP failed to log at a depth 
of 270 metres. The battery pack was replaced. It was evident that the supply of battery 
packs might not suffice. A spare pack was requested and arrived in Reykjavik. To avoid 
potential subsequent loss of data it would be advisable to renew the pack if the voltage drops 
to 32.2 volts. As it seems the power drain may be greater in bottom tracking modes it may be 
prudent to use only water tracking at lower voltages. 

Data quality: Apart from the loss of data mentioned above the data quality from the ADCP 
was good throughout.

Backscatter: Acoustic backscatter from the ADCP is logged as a beam by beam measurement. 
BBLIST is an RDI program that allows data to be converted to an ASCII file format. This can 
be run in a batch mode by using BBBATCH. Once the files had been converted they were 
read into PSTAR and a program was written to enable the target strength to be generated after 
merging with the temperature and salinity data from the CTD. This compared favourably with 
the Vessel mounted ADCP data. Further investigation could, using the calibrated VMADCP 
as a standard yield quantitative values for acoustic backscatter throughout the water column

Remarks: The LADCP seems to function well and generates useful information on both 
currents and backscatter. The battery supply has its limitations though and thought should be 
given to alternatives to the present set-up as cold water seems to reduce the output of alkaline 
cells quite considerably.
(M.C.Hartman)


3.10.1 LADCP Processing for Current Profiles

A brief account of the LADCP current data processing, file nomenclature and directory 
structure is provided in the following lines. Little emphasis is put into a detailed description 
of the main programming tools used, since these are part of a standard software package 
developed by Eric Firing at the University of Hawaii.


Outline of LADCP current calculation method

This section aims to offer a very simple introduction to the LADCP current calculation 
method, so that the files and programs listed in sections below can be placed in their actual 
context. For a more self-explanatory account of this method, see reference.

The Broad Band LADCP used during Vivaldi 96 was designed to measure the instantaneous 
relative velocities of scatterers in the water column by taking advantage of the Doppler 
frequency shift, phase changes and correlation between coded pulses transmitted and received 
by the LADCP's four transducers. Conversion of this raw data stream to a profile of absolute 
currents involved an elaborate calculation method.

Firstly, Doppler shifts needed to be scaled to velocity units by taking into account the depth-
dependent sound velocity (estimated from CTD T and S measurements). Directions could be 
inferred from trigonometric calculations based on the geometry of the transducer set, the 
orientation of the package (measured with a flux gate compass) and the local magnetic 
declination. The depth of the instrument was calculated from the integration of the measured 
vertical velocity and later adjusted to match the depth given by the CTD's pressure sensor.

The velocities corresponding to each single ensemble (or, in effect, to each transducer ping) 
were gridded in bins of depth set either to 8 or 16 meters, depending on the cast. Statistical 
rejection of spiky measurements within each of these bins followed.

In order to reject the unwanted motion of the instrument (but also the barotropic component 
of the current), shear profiles were calculated for each ensemble. A complicated editing scheme 
preceded this shear calculation. A final shear profile (baroclinic current) was derived by real-
depth gridding of the shear profiles calculated for individual ensembles. It was hoped that any 
relative velocities introduced by the high-frequency motion of the CTD package would be 
smoothed out by this repeated averaging.

The barotropic component of the flow was finally calculated from bottom-tracking 
measurements (bottom-track mode) or, in most occasions, in an integral sense from differential 
GPS positions of the ship (water-track mode).

The definitive velocity profile was hence obtained as the sum of the baroclinic and barotropic 
components.

During Vivaldi 96, no specific error calculation was performed, but a figure of the order of  2 
cm/s may be quoted from previous surveys. Profiles of shear standard deviation were included 
in the cast log sheet folder. Considerable contamination by tidal currents was appreciated all 
the way from Barra Head to Lousy Bank, while internal wave signals were obvious 
throughout the cruise.


Relevant PC files

The raw data were downloaded from the LADCP into a devoted PC after each cast and stored 
as a binary file called dNNN.000 in the c:\ladcp\d223\dNNN directory, where NNN stands for 
the last three digits of the CTD cast number, e.g. raw data from cast 12943 were stored in the 
file c:\ladcp\d223\d943\d943.000 .

The command file (named *.cmd, where * denotes any character string) containing the 
operating instructions (setting of track mode, bin depth, etc.) given to the LADCP previously 
to deployment was stored in the same directory.

Text files of the form dNNN.scn are the output from the program 'scanbb' and contain general 
information about the LADCP cast, such as start, bottom and stop times/ensemble numbers.

Text files called dNNN.cnt store information required by the program 'loadbb' to transfer the 
raw binary data to the CODAS database. Database files may be recognised by their .blk 
extension.


Other PC files

In the c:\ladcp\d223\dNNN directories, other files involved in the instrument deployment or 
data recovery might be encountered.
lady.def is a standard definition file for input to 'bbsc', the program that controls the LADCP 
deployment and data flow after recovery.
Also in the above directory, loadNNN.log keeps a log of the loading of raw binary data to the 
CODAS database by 'loadbb'.

In c:\bbadcp, files named dNNN.txt are the log of the 'bbtalk' session (testing the state and 
functioning of the instrument) previous to deployment. Only casts in Leg 1 and beginning of 
Leg 2 were logged into these files. The details of the sessions for every single cast in the cruise 
are to be found in the cast log sheets.

In c:\bbadcp\deploy, files of the type dNNN.log store the deployment information output by 
'bbsc'.



Relevant SUN files

Cast directories: A directory called dNNN (where NNN again denotes the last three digits of 
the CTD cast number) was created for each cast under /data52/ladcp/ladcp/ladyproc/223_viv . 
Most PC files were copied across to this dNNN cast directory for processing.

A whole variety of files were created and manipulated during the different processing stages, 
and no mention will be made of the majority of them for reasons of clarity. The processing 
procedure may be summarised in four steps:

1- create a SUN version (files named dNNNs*.blk) of the CODAS database using the program 
'mkblkdir' .

2- incorporate CTD pressure, temperature and salinity data into the CODAS database in 
order to obtain the best possible estimates of depth and sound velocity. This is done using 
'add_ctdbb' after running the MatLab programs 'doctd' and 'set_NNN' .

3- use the Perl script 'domerge' to calculate mean shear profiles (baroclinic component of 
current) and apply corrections and editing options (these are stored in a file called merge_.cnt 
and were kept constant throughout the whole cruise).

4- introduce effect of ship's motion and calculate barotropic component of velocity. (The 
navigation data used for this purpose during Vivaldi 96 were the 1 s GPS positions from the 
~/rawnav directory. The short FORTRAN program 'temp' was written to filter out redundant 
positions, since this was a cause for errors during later processing). The MatLab script 
'do_abs' calculates absolute velocities and produces a standard set of curves for each cast. 
These plots were regularly stored with their correspondent cast log sheets.

LADCP directory: Under /data52/ladcp/ladcp/ladyproc/223_viv a directory called ladcp was 
created. The ASCII files containing the final absolute velocities averaged in 5 m bins for each 
single cast (nomenclature ldpNNN.asc) may be found in this directory, along with their 
PSTAR versions ldpNNNNN (where NNNNN stands for the five-digit cast number). The 
script 'ladcpexec' was used to do the ASCII to PSTAR format conversion. Another useful 
file, latlon.asc, stores a four-column list of NNN (three last digits of cast number), cast 
latitude, cast longitude and maximum depth from which the LADCP recorded good data.

Other SUN files: The SUN files that have not been mentioned in the above section follow the 
standard naming convention adopted in Nick Crisp, Lisa Beal and Robin Tokmakian's 
LADCP data processing manual. Most of them are either short logs of the execution of 
various processing programs or record fragments of the cast's data at different processing 
stages. Refer to the manual if further information is required.

Archiving: Data stored in the PC were recorded into an EO while conserving the original 
directory structure.


References

Fischer, J., and M. Visbeck 1993: Deep velocity profiling with self-contained ADCPs. J. 
Atmos. Oceanic Technol. 10, 764-773.

(A.C.Naveira Garabato)


3.10.2 LADCP Absolute Backscatter

An estimation of the absolute backscatter coefficient (Sv, measured in dB) for the whole water 
column surveyed in each single CTD station during Vivaldi 96 was obtained from echo 
intensity (E, in counts) measurements recorded by four transducers in an LADCP, which was 
lowered with the CTD package. The method used in this calculation was a variation of that 
described in RDI 1990 (see reference), which in mathematical terms may be expressed as

Sv = 10 * log10 [ 4.47*E-20 * K2 * Ks * (Tx + 273) * (10^(Kc * (E - Er) / 10) - 1) * R2) / c / 
P / K1 / E(-2 * a * R / 10) ]

where

Tx = transducer temperature (C)
P = transmit pulse length (m)
R = range along beam to scatterers (m)
Er = real-time reference level for echo intensity (count)
Kc = conversion factor for echo intensity (dB/count)
K2 = system noise factor
Ks = frequency-dependent system constant (ratio of system's AGC bandwidth and square of
 transducer's diameter)
K1 = real-time power into the water (W)
a = absorption coefficient of water (dB/m)
c = speed of sound (m/s)

Below follows a brief, step-by-step account of the algorithm developed for the calculation of 
Sv.


Data conversion to PSTAR

Data were extracted from the raw binary files in the LADCP PC (*.000 files) and converted to 
ASCII format by using BBLIST, a program included in the LADCP software package. The 
listing format was saved in a file named ascii2.fmt (which has been backed up along with the 
other PC files) and contained, in the following order, jday, transducer temperature (txtemp), 
bin depth (bindepth), echo intensity from each of the four transducers (amp1, amp2, amp3, 
amp4), % good pings from beam 4 (good), pitch of the CTD package (pitch), roll (roll) and 
heading of LADCP (heading).

The ASCII file thus created was copied to a SUN terminal and converted to PSTAR with the 
pascin exec ascinexec.


Absolute backscatter calculation routines

A series of scripts and a PSTAR program were written during the development of the 
absolute backscatter calculation routine. These will be listed and commented on in order of 
execution.

 lacexec1

This short script copies the PSTAR file containing raw echo intensity data and the CTD file 
for the relevant station to the working directory, merges them on time (originally, LADCP and 
CTD files use different year day conventions, so this has to be accounted for) and calculates 
the pressure at the scattering layers by adding the pressure at the CTD package depth and the 
LADCP bindepths.

 lacexec2

Another simple script, lacexec2 finds the data cycles (in the file output from lacexec1) for the 
turning points in the package pressure. This is so that the file can be split into a downcast and 
an upcast part at future stages.

 lacexec3

lacexec3 produces the separate downcast and upcast files to be calibrated. These files include 
all the original LADCP variables and temperature and salinity from the CTD file.

 lacal

The calculation of Sv is accomplished in the PSTAR program lacal. In essence, lacal applies 
the equation above to the raw LADCP echo intensities. The main practical difficulty consisted 
on estimating some of the terms in this equation, and this will be the subject of the following 
lines.

Being instrument-dependent parameters, K1, K2 and Ks should have been obtained from the 
manufacturer's specifications. However, no such information was available on the ship, so the 
decision was taken to introduce a scaling term multiplying the expression inside the log (this 
was expressed, taking advantage of the properties of logs, as a parameter (Z) added to the 
original Sv). Given that K1, K2 and Ks are supposed to be constant to a good approximation, 
this approach should be valid. The value of Z for each of the four LADCP transducer beams 
was determined by reference to the vessel-mounted ADCP backscatter measurements, which 
had been reliably calibrated with well-established system parameters. For the sake of a 
magnitude scaling, K1, K2 and Ks were set to typical values from a VMADCP of 
characteristics similar to our self-contained one:

K1 = 74.6 W
K2 = 3.46
Ks = 4.17 * E5
Z(beam1) = 27.0
Z(beam2) = 28.3
Z(beam3) = 28.5
Z(beam4) = 31.7

Kc was chosen accordingly:

Kc = 0.42 dB/count

The real-time reference level for echo intensity could be estimated by RDI's in situ method, 
by which Er is set to the value of E returned when the echo intensity counts reach a minimum 
value and flatten out, usually in deep water, well away from interfering signals generated by 
the ship. This revealed the following Er values:

Er(beam1) = 32.0
Er(beam2) = 32.0
Er(beam3) = 37.0
Er(beam4) = 36.0

Profiles of sound speed could be inferred from CTD T and S measurements, using

c = 1412.0 + 3.21 * T + 1.19 * S + 0.0167 * depth

The range along beam to scatterers was expressed as

R = ( Bk + | ( P - B) / 2 | + N * B + P / 4 ) / cos  * c / 1475.1

where

Bk = blank beyond transmit (m)
P = pulse length (m)
B = bin depth (m)
N = bin number
 = angle of transducer beams to vertical = 30  in this case
c = sound speed

And the absorption coefficient

a = A1 * P1 * f1 * f2 / ( f2 + f12 ) + A2 * P2 * f2 * f2 / ( f2 + f22 ) + A3 * P3 * f2 (dB/km)

where

f = LADCP frequency = 150 kHz

Boric Acid contribution:
A1 = 8.86 / c * 10^(0.78 * PH - 5) (dB/km/kHz)
P1 = 1
f1 = 2.8 * ( S / 35 )^0.5 * 10^( 4 - 1245 / (T + 273) ) (kHz)
PH = 8

MgSO4 contribution:
A2 = 21.44 * S / c * ( 1 + 0.0025 * T ) (dB/km/kHz)
P2 = 1 - 1.37 * E-4 * depth + 6.2 * E-9 * depth2
f2 = 8.17 * 10^(8 - 1990 / (273 + T) ) / ( 1 + 0.0018 * (S -35) ) (kHz)

Pure water contribution:
A3 = 4.937 * E-4 - 2.59 * E-5 * T + 9.11 * E-7 * T2 (dB/km/kHz)
P3 = 1 - 3.83 * E-5 * depth + 4.9 * E-10 * depth2

Besides the strict calculation of Sv, an editing scheme was designed to smooth out part of the 
high frequency noise that was originally encountered after the calculation. The criteria used 
were based on % good pings (beam 4 was used since it was noticed that it controlled the 
editing of the velocity data), pitch and roll, and statistical rejection of spikes (based on binning 
of data in depth cells and deletion of those data cycles which differed by more than a certain 
threshold from the mean value of echo intensity in their corresponding cell).

The editing control parameters for the pitch and roll criterion were input, along with Er values, 
Z values and system-dependent constants, in a control file named lacal.cnt . The factor 
controlling statistical editing was embedded in the body of the lacal program (a parameter 
called 'factor').

Having this information present, the operation of the lacal program is straightforward. Its 
output includes nine new variables: sv1, sv2, sv3, sv4 (Sv for each of the transducer beams), 
glin1, glin2, glin3, glin4 (parameters related to the expression inside the log in the equation for 
Sv, so that Sv = 10 * log10 (glin * E-11) + Z ) and glinav (the average of glin1, glin2, glin3, 
glin4). The purpose of the glin variables is to ease data gridding in the future. It was judged 
that gridding of absolute backscatter coefficients should be implemented on the linear 
expression inside the log, and not on Sv itself, given the special properties of logarithms.

lacal was usually run in the form of a script: lacal.exec .

 lacexec4

The script lacexec4 grids the output from lacal and produces a smoothing filter based on the 
autocorrelation statistics of the gridded data.

 lacexec5 / lacexec5.b / lacexec6

These three short scripts apply the smoothing filter obtained by lacexec4. The variable svbest 
is the best estimate of Sv after calibration, editing, gridding, smoothing and beam averaging.


 lacexec7

lacexec7 cleans up the working directory.



Future work

Over the range of the VMADCP, the LADCP showed the potential for measuring reliable 
absolute backscatter coefficients. Even with the crude calibration applied here, Sv, as 
measured by the LADCP, was usually within 3 dB of that measured by the VMADCP. It 
could be appreciated that VMADCP measurements are probably unreliable under 450 m, and 
that a lot of interesting structure is to be found in the deep ocean, outside the reach of the 
VMADCP. It might be feasible to use the LADCP, in conjunction with in situ net sampling, 
to survey deep zooplankton populations and ultimately use this approach to infer a 
calibration method for converting absolute backscatter coefficients into biomass 
concentrations. During Vivaldi 96, nets were deployed at several depths in a few single 
stations in order to infer the species compositions of various backscatter peaks. The samples 
were not analysed on board, but obvious differences in species between the peaks could be 
visually observed.


Archiving

Owing to this work having started as an experimental trial, no log was kept of processed data. 
Nevertheless, the following instructions should provide a sufficiently clear perspective into 
the character and contents of each file.

All archiving of LADCP backscatter data was performed onto EO22306

The PSTAR files containing the raw echo intensity data as read from the *.000 files in the PC 
were archived under directory 'source'. Their names followed the pattern lbsNNNNN.sr 
(where NNNNN is the five-digit station number) and their data names lbsNNNNN .

The non-gridded calibrated files were recorded under 'cal', named lbsNNNNN.dn and 
lbsNNNNN.up (for downcast and upcast, respectively) and same data name as above.

The gridded calibrated files, lbsNNNNN.dn.gr and lbsNNNNN.up.gr, were archived under 
'cal.gr', with the same data name as above.

References

RDI 1990 Calculating absolute backscatter, Technical Bulletin ADCP-90-04, RD Instruments, 
San Diego, California, 24 pp.
(A.C.Naveira Garabato, M.C.Hartman)


3.11 Nets

At most CTD stations shallow plankton nets were used to collect zooplankton samples. The 
mesh size was 500__m except for the cod-end which was 200 _m. The samples were 
preserved in kilner jars with formalin solution. Table 6 shows the depth of the net-haul at each 
station.

4. UNDERWAY MEASUREMENTS

4.1 SeaSoar

4.1.1 Winch

The horizontal drum SeaSoar winch was used for a total of 24 survey deployments during the 
cruise, without any operational delays. However the excessive rough weather took its toll on 
the cable and fairing, and some mechanical problems were encountered.
(R Bonner)


4.1.2 Deployment and Recovery

Following discussions with RVS prior to the cruise, it was proposed to hang the SeaSoar 
towing block off the starboard aft crane during launch and recovery, then transfer it to and 
from the Aft gantry auxiliary arm for survey towing. The SeaSoar winch was sited on the 
starboard side of the aft deck, in alignment with the auxiliary arm and a Lebus 3 tonne winch 
sited adjacent to it, with its warp running through the auxiliary arm block. This winch was to 
allow height adjustment of the SeaSoar block and enable its transfer to and from the crane.

Prior to deployment, restraining lines were fitted to the SeaSoar block and run through the 
vehicle wing ends. These were to assist with its control during launch. With the vehicle on 
deck under the gantry and the SeaSoar block hanging above it on the crane. The launch 
procedure was then to raise the vehicle with the SeaSoar winch, slowly swing it outboard with 
the crane, whilst slowly paying out on the winch. When the crane was fully extended aft, the 
vehicle could then be lowered into the sea and its stray lines pulled from the wings. Once in 
the water, the ships speed could be increased from 2 to 4 knots and the tow cable paid out to 
approximately 200 metres before transferring the SeaSoar block from the crane to the auxiliary 
arm. The gantry was then paid out, the SeaSoar block stray lines secured to cleats and the 
remainder of the cable paid out. After a few deployments, it became apparent that control of 
the vehicle using stray lines, was good enough to dispense with the use of the crane 
completely for launching and all further ones were done directly from the SeaSoar block 
hanging via the auxiliary arm block. The recovery procedure was effectively the same as for 
launches but reversed. However the crane was still essential for recoveries in all but the 
calmest of seas, as it could position the SeaSoar block far enough aft to prevent the vehicle 
being washed against the stern and damaged.

When the winch was first run up on board, it was discovered that the drum had seized up. 
Only by continually driving it in alternate directions, did it eventually start to move - coupled 
with a heavy rumbling noise at the power pack end of the drum. Following lubrication of the 
bearings and drive gears, no further seizing was experienced. Hydraulic oil leakage was another 
problem. There were several in the system pipework, but the worst was from the brake unit 
cylinders, which appear to have corroded and damaged the seals. These will require urgent 
repair upon return to UK.
 
The vehicle was often recovered in heavy seas and gale force winds and on one occasion in 
winds in excess of 50 knots. Most of the damage done to the cable and fairing occurred during 
these operations. The conducting cable had to be reterminated 4 times, either because it had 
got hooked on the wing end plates (now modified), or because the vehicle had been flipped 
over by large waves immediately following launch. The cable was seriously damaged at the 
inboard end at sea level, when the CPR cable became entangled around it in rough weather 
during the second line. For the subsequent 22 lines, the vehicle had to be kept on a shorter 
tow, with the damaged section of cable remaining on the drum in order not to overload it. This 
shortened the usable length of the cable by 60 metres and the 4 reterminations shortened it by 
approximately a further 25 metres. This is on top of the cable already being supplied 40 
metres short. Every recovery brought instances of damaged fairing which needed cutting off 
before winding on to the winch. The worst case of which was caused by a long-line running 
down the fairing. Further refinement of the winch spooling will reduce the amount of fairing 
damage and negate the need for someone to guide every length of fairing on to the spooling 
sheave with a broom.
(R Bonner)

The Sea Soar fish was deployed from the auxiliary arm on the aft gantry. The secondary 
sheave that Sea Soar was towed from, was transferred to the starboard crane during recovery 
to prevent it swinging about in rough seas.
(Pete Mason, Jeff Jones)


4.1.3 Equipment

The following equipment was fitted to the SeaSoar for this cruise.

Neil Brown / General Oceanics MkIIIb CTD ( SOC modified )
Focal Technologies Optical Plankton Sampler ( OPC )
Chelsea Instruments Aquatracka III Fluorometer.
Chelsea Instruments Photosynthetically Active Radiation ( PAR ) sensor.

The SOC SeaSoar winch MkII ( horizontal drum, 750 metre cable capacity ) was used for 
towing the vehicle throughout the cruise. 

Cruise Preparation.

In preparation for the cruise a new 7-conductor Rochester cable was faired with a mixture of 
old and new fairing and wound onto the winch. The length of cable was found to be 
approximately 710 metres in length, some 40 metres shorter than the 750 metre capacity of 
the winch. The reason for this shortfall is believed to be due to the fact that an error was made 
when measuring out cable for our small winch, which was removed earlier from the single 
drum intended to supply both winches. Unfortunately this problem was only discovered late 
in preparation for the cruise and time was not available to replace this tow-cable 

A new SeaSoar software/hardware vehicle controller system was prepared for use on a major 
cruise for the first time after initial tests on a trials cruise aboard RRS Charles Darwin earlier 
this year.
 
The SeaSoar vehicle and two hydraulic actuator units were prepared and tested at SOC before 
the cruise. A spare set of SeaSoar wings, hydraulic actuator with spares, two tail fins, an 
impeller and a bomb weight were supplied for the cruise.


SeaSoar Survey. 

The first vehicle deployment ( Run 1 ) was carried out with OPC, fluorometer and PAR 
sensor attached, on day 285. Whilst deployment was still underway, on a heading dictated by 
prevailing wind and sea swell direction, the water depth shallowed rapidly. Immediate action 
was taken by the winch driver and the bridge officer to recover the vehicle and gain deeper 
water. On recovery of the vehicle impact damage was seen to have torn the OPC and its 
mounting frame free of the vehicle, damaged the fibreglass nose of the vehicle and pushed the 
nose mounted fluorometer back into the main body of the vehicle. Following repair, fitting of a 
bomb weight, and cable retermination the vehicle was redeployed and run without the lost 
OPC sensor. 

Persistent poor weather conditions, over 26 deployments and recoveries and damage due to 
fishing lines led to a gradually reduced tow depth capability during the cruise. Initially over 
400 metres was achieved but by the end of the cruise a maximum of only 365 metres depth 
could be reached under even ideal conditions. Several wing end plates were lost due to towing 
cable getting caught around the wing almost always during deployment or recovery 
operations. These snags also bent the impeller occasionally but these knocks could be 
straightened back into shape. One impeller blade was snapped requiring the use of the spare 
unit. After an initial cable termination, one precautionary termination and two repair 
terminations were made during the cruise. Winch performance and deck operations are 
discussed fully in another section of this report. 

CTD SHALL01 had been modified to a dual conductivity cell format, so that if fouling 
occurred on one cell data could be used from the other cell until the fouling cleared itself. Data 
was rarely lost due to fouling of both cells. Data quality was good throughout and the CTD 
required no repair or internal adjustments. 

Despite a rather heavy impact during Run 1 the Chelsea Instruments Aquatracka fluorometer 
worked satisfactorily on each run.

The PAR sensor also performed reliably. Some noise spikes were seen in its data output but 
this problem was cured by replacement of its electrical lead between the sensor and the CTD. 

The SeaSoar hydraulic unit 02 was used throughout the cruise and showed no traces of leakage 
of hydraulic oil during periodic checks. The spare unit taken was therefore not required.

Vehicle 'flight' control was carried out by a software program running on a personal 
computer, and a hardware interface, both developed by John Smithers. During the Leg 1 of 
this cruise the program was further debugged and refined. It now provides the SeaSoar 
operators with a versatile control, and SeaSoar performance logging system, to replace the old 
hardware controller and chart recorders. This system was most successful and will be used on 
all further SeaSoar cruises. 

The vehicle and sensors performed well during the cruise. Lack of working depth was 
disappointing but during a cruise in excess of 7 weeks carried out in such very poor weather 
conditions it would be unrealistic to expect to maintain optimum performance from any faired 
tow cable. A total of 24 runs were carried out over both Legs of the cruise during which 
SeaSoar was towed for a total distance of 8960 kilometres. 

(R.Kirk, J.Smithers, R.Bonner, S.Watts)


4.1.4 Data Processing and Calibration

The SeaSoar was fitted with pressure, temperature, two conductivity cells, a fluorometer, 
oxygen and light sensors. Standard SeaSoar processing techniques were followed. Every 4 
hours, the raw data were calibrated, plotted and corrected for salinity offsets to obtain the 
best possible relative calibration. Absolute calibration is described in 4.1.5. The initial 
calibration values used are listed in Table 12. Values for pressure, temperature, oxygen and 
light were taken from OTD calibration sheets. However, oxygen values were too noisy to be 
useful. Conductivity ratios for the two conductivity cells were adjusted so that initially 
obtained T/S curves were a reasonably close match to calibrated CTD T/S curves. 
Overplotting down and up T/S curves for the master conductivity cell (paired with the 
platinum resistance thermometer) showed slight hysteresis, which was minimised in the usual 
way by adjusting the time constant used to speed up the PRT from 0.15 to 0.18 seconds. 
However, slight hysteresis between the calculated salinities from the two cells remained.
Differences between down and up cast values of sal1-2 were initially small (plus minus 0.003) 
and were ignored. However, the offset increased to 0.01 or larger once the temperature range 
from top to bottom of each profile increased, making correction of salin using salin2 difficult. 
The T/S curves for salin2 showed definite hysteresis between down and up, so it was 
concluded that, for unknown reason, the two conductivity cells needed to be corrected using 
different temperature time constants. There is no facility for this in ctdcal, so a second 
shalctd(2).cal file was created with a different time constant in it. Ctdcal was run a second 
time. and the resulting files were pjoin'ed so that only salin2 was replaced. This was done as a 
trial on sa223085, but not applied to the master data set. It was found that 0.25 sec for C2 
brought the T/S curves together, compared to 0.15 for C1. Plots showed that the hysteresis 
was much reduced but noise increased of course.
The new exec was used on sa223086. Plots of sal1-2 showed that the hysteresis was reduced, 
but noise was large, nearly swamping any temperature dependence. Pbins was therefore used 
it to bin sal1-2 as a function of temperature. Fit by eye to the resulting profiles (sa223086AN 
attached) looked close to 0.001 per degree C. Thus an arbitrary calibration of salin2 by
	salin2 (new) = salin2 (old) -0.001 * (11 - potemp)
should reduce the effect. This leaves salin2 unchanged only at potemp = 11C. ssexec1 was 
modified and applied to sa223087. It did reduce the oscillation of sal1-2 considerably. It was 
concluded that for 4-hourly processing (a) salin should be used as the master variable; (b) if 
salin is fouled with a constant offset, prefer to use finctd to correct it rather than swapping in 
salin2; (c) if salin fouls and drifts, swap in salin2, and use the values of sal1-2 at the start and 
end of the fouling to finctd the swapped bit of salin2. It is suspected that the electronics of 
the 2-cond old shallow CTD may be the problem, as similar problems occurred on the 
SWINDEX cruise Di213 (with FSI sensor in slot 2) and Polarstern. The problem went away 
on ps1 when P. Gwilliam tidied up the CTD boards and wiring. Possibly a vibration problem. 
Long term solution hopefully is to convert new shallow CTDs to use two conductivity 
sensors.

(R.T.Pollard, E.C.Kent)

A listing of the calibration file shalctd.cal is given in Table 12.


4.1.5 Salinity Calibration

The surface SeaSoar data were compared to a series of surface water bottle samples and the 
differences used to calculate final corrections to the SeaSoar salinities. The bottle samples 
were half-hourly and hourly underway bottle salinity samples were drawn from the ship's 
non-toxic supply in the Hangar. The non-toxic supply is drawn through an inlet pipe in the 
hull approximately 5m below the water line.

The underway samples were ftp'd from ASCII text files on a Macintosh and read into the 
PSTAR format (pascin) and time in seconds calculated (see  2.5.1, Thermosalinograph 
Temperature and Salinity Calibration). Surface SeaSoar data were obtained by appending all 
the 4-hourly files and using datpik to select data in the pressure range of 3-7 dbar. The bottle 
data were merged (pmerg2) with the SeaSoar data and the difference between the salinities was 
calculated (parith). Plots of salinity difference against time and against SeaSoar salinity both 
gave approximately straight lines with a constant offset for extended periods of time. Changes 
in the offsets occurred during breaks in SeaSoar runs e.g. port call, CTD section (Table 7, 
SeaSoar Deployments). The mean offset was calculated with phisto, with limits being set to 
exclude those points giving large offsets (e.g. bad sample data and steep salinity gradients). 
The salinity differences prior to calibration are illustrated in Fig.7 and listed in Table 8. The 
calibration was applied to the master run files (pcalib) and sigma0 recalculated. 

(N.P.Holliday)


4.1.6 Fluorescence Calibration to Chlorophyll

Continuous in situ fluorescence measurements in the top 400 m of the water column were 
recorded during RRS Discovery's Vivaldi 96 survey with a Chelsea Instruments Aquatracka 
III fluorometer mounted in the towed undulating fish Sea Soar. Chlorophyll a concentrations 
were inferred from these measurements by application of a modified version of the supporting 
point calibration method developed by V.H.Strass at the University of Kiel.

The supporting point calibration method is based on the surface chl a concentrations derived 
from underway TSG fluorescence data and so, ultimately, determined from bottle samples 
taken hourly from the ship's non-toxic intake. The calibrated TSG chl a (1 min) files were 
firstly regridded in 10 min bins (pavrge) and merged (pmerg2) on time with the gridded near-
surface (6-14 m) Sea Soar fluorescence record (c.f. non-toxic intake at 5 m depth). The 
mismatch between the TSG and Sea Soar depths was regarded as unimportant, given the deep 
well-mixed layers that characterised the area surveyed during Vivaldi 96. A series of 
calibration points was obtained in this way.

Fluorescence yield, the ratio of fluorescence to chl a concentration was then calculated for each 
of the calibration points and later plotted versus (uncalibrated) light intensity. It is a well-
established fact that the relationship between fluorescence yield and light intensity is that of a 
negative correlation, due to the photosynthesising apparatus of phytoplankton adapting to 
higher light levels by modifying its photoadaptive state. Besides this light quenching effect, 
other factors contribute to the high variability of the fluorescence yield: species composition, 
nutrient supply and physiological state of phytoplankton are known to heavily condition 
yield.

The supporting point method aims to account for these two types of contribution. Light 
quenching is removed by fitting a curve to the cloud of points in the fluorescence yield vs. 
light intensity plot, whereas species and other miscellaneous influences are brought into the 
calibration by shifting the curve vertically along the yield axis to a level determined by the 
local supporting calibration point. The assumptions are made that the variation of 
fluorescence yield with light follows, to a good approximation, the same curve for all the 
species present in the area (this seems to be confirmed by the reduced differences in scatter in 
the cloud of calibration points over the range of light intensities present), and that the curve 
level determined locally at the surface can be extrapolated to the whole water column 
(calibration of CTD fluorescence validates this hypothesis).

However, it should be noted that the reference yield time series used for calibration is not the 
simple ratio of fluorescence to chlorophyll a concentration calculated above, but a smoothed 
version of it. In the spatial scales at which underway sampling is performed, phytoplankton 
shows, in addition to broader trends, a fine natural patchiness which gets picked up by the 
yield. Considering that the horizontal spatial resolution of Sea Soar falls nearer the mesoscale 
range, this scattered small-scale information is, in practice, contamination, and has to be 
smoothed out. By using the central section of the yield's autocorrelation function (as 
calculated by a modified version of pcorr) as a filter (pfiltr), the desired smoothing can be 
accomplished, preserving yield variations at any scales larger than the fine phytoplankton 
patchiness but rejecting the latter.

Matlab facilities were used to find the best fit for the yield / light relationship. This turned out 
to be a function of the form

thyld = [ k * coth ( a * light + b ) + k1 * light ] * weight (1)

where

weight = 0.89 - atan [ ( light + 28 ) / 2 - 21 ] / z ,

thyld stands for theoretical yield, and k, a, b, kl, and z are variable fitting parameters.

In order to apply this function to the PSTAR SeaSoar gridded files, the PSTAR program 
flucal2 was written. The working routine of the programs consists, firstly, on calculating the 
local curve offset z3:

z3(ref) = yield(ref) - thyld(ref)

where yield(ref) is the yield at the local supporting calibration point and thyld(ref) is the 
theoretical yield at the same point as derived from (1). z3 is consequently extrapolated 
vertically. (Note that variables at the supporting points are labelled '14' in the output from 
flucal e.g. the light intensity at the supporting points is named 'light14'. The other new 
variables are referred to as in the equations above).

Once z3 is defined throughout the file, the yield can be derived at every single point n in the 
data set:

yield(n) = thyld(n) + z3(n)

And the chl a concentration is trivially calculated as

chl(n) = fluor(n) / yield(n)


Table 9 shows the values for the fitting parameters over the Sea Soar survey: These values 
were chosen after successive trials, and no exact mathematical routine was used. The error 
involved in this calibration is thought to be better than 10%. Obviously, the differences with 
TSG (and hence bottle) surface chl a concentrations are minimal, since the method forces the 
Sea Soar chl a to be very similar to the corresponding TSG chl a used for reference. A better 
way of estimating the uncertainty in SeaSoar chlorophylls is by comparison with CTD 
profiles between runs. A brief examination of these revealed errors of the order of the one 
quoted above. This figure is in agreement with the estimation in Strass' original calibration.


Archiving

The Sea Soar fluorescence was calibrated in sections consisting of five runs.

Runs 1 to 5 were saved in a file called ss223.chl.1-5 and archived as ss223r01.MJ .
Runs 6 to 10 were saved in ss223.chl.6-10 and archived as ss223r06.BG .
Runs 11 to 15 were saved in ss223.chl.11-15 and archived as ss223r11.BU .
Runs 16 to 20 were saved in ss223.chl.16-20 and archived as ss223r16.BV .

No calibration of the last four runs was produced on the cruise due to lack of time

References

Strass, V.H., 1989 On the calibration of large-scale fluorometric chlorophyll measurements 
from towed undulating vehicles. Deep Sea Research, 37, No. 3, 525-540.

(A.C.Naveira Garabato)


4.2 Optical Plankton Counter (OPC)

The OPC was lost on the first deployment of the SeaSoar on 11th October.



4.3 Continuous Plankton Recorder (CPR)

4.3.1 Deployment

Initially the CPR was deployed aft but on 13.10.96 the towing cable became entangled with 
the SeaSoar towing cable endangering it. Thereafter the CPR was towed from the port aft 
boom, which had been connected up to the auxiliary winch controls on the aft gantry. The 
CPR was deployed and recovered with the port crane and transferred to a cable from the 
auxiliary deck winch for towing. This proved to be successful and enabled safe deployment 
and recovery possible under the severe sea conditions experienced. 
(P.Mason, J.Jones)


4.3.2 Sampling

SAHFOS supplied 1 CPR fish and 3 loaded inner mechanisms for surface plankton sampling 
during Vivaldi 1996. A further 6 graduated sample silks and cover silks were provided to be 
loaded at sea. These were standard 270 5m silks which are capable of each filtering for 500 
nautical miles, with each graduation representing about 3m-3 of water. 40% formaldehyde, 
buffered with borax, was soaked into the cotton wool in the storage tank, to keep the samples 
preserved when they are in the CPR. The CPR was also fitted with a logging electromagnetic 
flow-meter designed not to impede flow through the recorder. 

After initial bad experience the CPR was deployed from a boom at the port quarter of RRS 
Discovery so that it was within 5 m of the stern and about 2 to 3 m below the surface. This 
short length of cable reduced the chance of entanglement with the SeaSoar in rough weather. 
However, the spatial resolution of the CPR is not good enough for this to matter when 
comparing the zooplankton to the SeaSoar data. It was towed simultaneously with the 
SeaSoar with only one leg being missed on purpose to conserve silk to enable sampling onto 
the shelf at the end of the cruise. While on station the CPR was recovered and the inner 
mechanism checked and topped up with 40% formaldehyde, and the silk was wound on one 
graduation to separate each run's samples.

The CPR was intended to be used to calibrate OPC data, because of its long term data sets 
(since 1931) and the large amount of data it has produced (it has been towed for more than 4 
million miles). Its data could be used, in the same way as underway data for chlorophyll, to 
calibrate OPC data while at the surface. However, it is still a useful biosurvey tool in its own 
right and its data is instructive.

The sample reels were removed from the mechanism and stored wrapped in lint in a 4% 
formalin atmosphere for analysis after the cruise.

A major problem of the silk snagging and ripping occurred on three runs, affecting two silks, 
(5.1, 5.2 and 6.1). Therefore data was lost entirely on runs 5.2 and 6.1, but only partly on run 
5.1. This was a result of inexperienced loading of the complex inside mechanism. The logging 
system also came loose three times during silks 5, 6 and 9; but was secured with modification 
to the mounting.

A list of CPR deployments is given in Table 16.

Reference
Draft (1996) SAHFOS Operations Manual for Continuous Plankton Recorder.

(A.T.Mustard)


4.5 Underway Nutrients

4.5.1 Samples

In addition to the underway nutrient analyser, discrete surface nutrient samples were collected 
from the non-toxic seawater outlet of the thermosalinograph mounted in the hangar deck. 
Samples were collected at the same time as salinity and chlorophyll samples and analysed on 
the discrete nutrient analyser. Duplicate samples were collected at one hourly intervals (on the 
half hour) whilst the ship was underway . One duplicate sample was stored in the refrigerator 
and analysed within twenty four hours of collection and the other duplicate was stored in the 
cold room (at 5C) in case the other sample spoiled. If this was not the case then the duplicate 
sample was discarded at a later time. 2032 underway samples were analysed over the course 
of the two Legs. The results from these analyses showed that initially surface nutrient 
concentrations were reduced. These values gradually increased throughout the course of the 
cruise.


4.5.2 Ultraviolet Measurements

A UV nitrate sensor similar to that used on the CTD-rig was mounted in the hangar deck and 
supplied with water from the non-toxic seawater supply. Measurements were made at a 
frequency of 0.5 Hz for the entire period of the cruise. The data was logged to the ship's level 
A. Nitrate concentrations derived from the analysis of the hourly discrete samples will be 
used to calibrate the underway data. The data from the nitrate sensor was imported into 
PSTAR and will be time averaged over 10 minutes and corrected for changes in salinity to 
produce a continuous record of surface nitrate concentrations measured over the course of the 
cruise.

(M.S.Finch)


4.6 Sample Chlorophyll

The chlorophyll samples from the non-toxic supply were analysed together with the samples 
from the bottles on the rosette sampler (see  3.9)




5. FLOATS

Seven profiling ALACE floats, purchased from Webb Corp., were deployed in the Irminger 
Sea during the cruise. Deployment positions were chosen with reference to the axis of the 
basin, which runs roughly SW-NE, with a view to examining the (cyclonic?) circulation around 
the basin. Accordingly, 3 were deployed on 60N in the western half and 4 on the old IGY 
line SE from Cape Farewell, in the eastern half.

Preparation, wake-up and deployment were essentially trouble-free and performed in 
accordance with the instructions in the "Owner's Handbook" provided by Webb Corp. with 
the floats. Deployment of the first four floats (see Table 10) was over the stern, on station 
after completion of other overside activities, with the rail down. Worsening weather made this 
seem rather unsafe; also, two of the TD floats had to be put over on the fly, so the remainder 
were deployed from the lee (starboard) quarter.

One item of damage occurred. The final float's aerial was bent about three inches from the end 
after a violent roll caused the float to slide off its preparation mount in the deck lab and hit the 
lab wall. The aerial was strengthened with a length of self-sealing shrink wrap.


(S.Bacon)



6. CRUISE LOGISTICS

Mobilisation

Mobilisation for the cruise took place in Falmouth, Cornwall and was scheduled to commence 
on Tuesday September 25th at 1200. However, to make cost effective use of the equipment 
transport, it was decided to use the same trailers that took equipment to Falmouth, to be used 
for the return of the previous cruise equipment to SOC. This necessitated all Di223 
equipment with the exception of that in the boxvan, to be loaded on trailers by Friday 20th 
September at SOC, to meet the vessel on arrival at 0900 on Tuesday 24th.

The trailers were delivered to SOC on Thursday 19th and all loose non-delicate boxed items 
were loaded in 20' and 10' containers. The first trailer carried 2 x 20' containers, one with this 
cruise equipment and one empty Dutch-owned unit, for shipping equipment from the 
previous cruise back to Holland. The second trailer carried the 10' container plus all large deck 
mounted items, including the SeaSoar winch, CTD rosette frame, CTD deck track and the 
SeaSoar vehicle. Whilst the boxvan carried loose delicate items.

The trailers and boxvan were all at Falmouth docks to meet the vessel at 0900 and the first job 
was to offload the trailer loads on to the quay to enable backloading of the previous cruise 
equipment. Items in the boxvan were loaded directly on to the ship. Backloading of the trailers 
continued all day and into the next morning, until they were fully loaded and ready to depart. 
Loading of the vessel commenced before lunchtime and the initial requirement was to get the 
20' container unloaded in order that the CFC equipment could be set up and purged with gas. 
delivery of the gas and liquid Nitrogen had taken place as arranged for that morning and once 
the CFC team had fitted extended bench tops in the Chemistry lab, the equipment could be 
installed. With the container unloaded and stowed in one of the container slots, the remaining 
priority was to load the deck mounted equipment. The SeaSoar winch and 2 RVS winches for 
the SeaSoar block and towing the CPR were fitted on the aft deck and the CTD track and 
CTD Rosette frame were fitted along the starboard deck, below the gantry. That morning the 
Met team had also arrived and commenced installation of the JRD met instruments and CFD 
instrumentation. On Thursday, with all equipment on board, the RVS divers were able to 
carry out the installation of the newly delivered ACCP, whilst setting up of equipment in the 
labs continued apace. By Friday evening everything was deemed as ready for sea and the 
vessel sailed on time on Saturday morning.

(R Bonner)



7. CRUISE DIARY

Table 17 gives the conversion of dates to days of the year for the period of the cruise.

Th 26.09.96
1000	Begin logging GPS data in port

Fr 27.09.96
1005	DGPS activated for tests in port

Sa 28.09.96 
0800	Depart Falmouth
2208	ADCP logging ceased for unknown reason.

Su 29.09.96 
1200	Two casts in the Irish Sea to test CTD, LADCP and collect water to calibrate CFC 
equipment.

Mo 30.09.96 
0154	Lack of ADCP logging discovered. Recovered from PC hard disc.
0631-0910	Zigzag runs to calibrate ADCP.
a.m.	Water found to have leaked into better of two salinometers.
1210	Start Rockall Trough Hydrographic Section at Barra Head.
2230	Wire test

Tu 01.10.96
2000	Problem with oil pressure sensor on winch
2200	Short circuit in conducting core cable.

Th 03.10.96
0045	Complete Rockall Trough Section at Rockall Island. Start hydrographic section to 
Lousy Bank.
0800	Loss of power to computers due to short in vacuum pump.
1400	Hove to due to swell causing excess loading on conducting core cable.

Fr 04.10.96
2345	Resume Rockall-Lousy Bank hydrographic section with station RL04/12960.

Su 06.10.96
0226	At station RL13/12969 end Rockall-Lousy Bank Section.
0400	Start Iceland Basin Section at station IB01/12970.
0453	At end of station IB01/12970 the conductivity cell was damaged by a Niskin bottle 
being shaken off its mounting and had to be replaced.
0710	Station IB02/12971 problem with CTD altimeter.
1140	Station IB04/12973 aborted due to heavy swell.
1415	After removal of old, large transmissometer, nitrate sensor and 5 Niskin bottles station 
IB04/12974 successfully attempted. Altimeter works again. Apparently bad nitrate sensor 
signal was affecting fluorometer and altimeter.
2015	After Station IB05/12975 station work was suspended by the Captain due to adverse 
weather conditions (Bft 8-9).

Mo 07.10.96
Hove to due to high winds (WSW 8) and heavy swell (~10m), though sunny.
It became apparent that the ancillary channels in the Level A/B/C logging of the data from the 
CTD package had been jumbled since the beginning of the cruise necessitating reprocessing of 
the CTD data and reappraisal of the apparently erroneous functioning of the in-situ nitrate 
sensor.
1900	Set course for Station IB06.

Tu 08.10.96
Still hove to. Wind WSW 9-10.

We 09.10.96
Still hove to.
2200	Attempt to start Station IB06/12977 but winch blew a fuse and cable needed 
reterminating.

Th 10.10.96
0100	Start Station IB06/12977. Hydrographic Section Lousy Bank-Iceland resumed, but 
only even stations.
1445	One of two Electron Capture Detectors on CFC equipment reported contaminated. 
Spare ordered for Reykjavik.

Fr 11.10.96
0830	End Station IB19/12983: End of Iceland Basin Section. Plankton net to 500m.
1335	SeaSoar deployed.
1745	SeaSoar recovered without optical plankton counter.
2340	SeaSoar redeployed.

Sa 12.10.96
1650	SeaSoar recovered to reterminate towing cable.
2010	SeaSoar redeployed.

Su 13.10.96
0400-0600	SeaSoar recovered with difficulty due to entanglement of towing cable with 
CPR towing cable. Since then hove to due to bad weather (ENE Force 10).

Mo 14.10.96
1605	Start hydrographic station near Z60/12984.
1910	Deploy SeaSoar.

Tu 15.10.96
1500	Deploy CPR from port airgun boom.
1800	Alter course to west at Z57 without stopping for a station.


We 16.10.96
0500	Recover SeaSoar and CPR. Lot of fairing damage, probably long line. Plenty fishing 
boats seen yesterday. Port crane u/s so CPR recovered using handy billy. Station YZ57/12985 
at 57N, 22 40'W.
1045	SeaSoar tailfin/radiometer support damaged in attempted deployment when steadying 
line tangled.
1255	SeaSoar deployed.
1315	CPR deployed. Course 335 towards Y60.

Th 17.10.96
1300	Change course at Y60 to 305, but no station.
1630	Recover CPR and SeaSoar for Station Y60A/12986: CTD and net
1950	Redeploy CPR and SeaSoar. Start following Topex/Poseidon track.

Fr 18.10.96
ca. 0300	Cross Reykjanes Ridge into Irminger Basin.
1330	Recover CPR and SeaSoar for deep CTD cast and net at Station X615/12987
1635	CPR and SeaSoar redeployed. Continue course NW towards centre of Irminger Basin.

Sa 19.10.96
0200	Recover CPR and SeaSoar for Station X63A/12988
0600	Redeploy SeaSoar but not CPR and tow off ENE towards Station Y63A.

Su 20.10.96
0230	SeaSoar recovered for Station Y63A/12989.
	Steam back 25 miles for Station Y63B.
0955	Station Y63B/12990 completed. Only sampling for physics.
	Set course for Reykjavik testing ADCP and ACCP on the way.

Mo 21.10.96
0800	Docked Reykjavik

Tu 22.10.96
0915	Sailed when safety briefing ended. Dogleg to first CTD station to avoid shallowest 
part of Reykjanes Ridge
2348	CTD 12991 at shelf edge, Y63.

We 23.10.96
0138	Begin SeaSoar Run 6
1300	Briefed crew.

Th 24.10.96
0143	CTD 12992 at Y60
0419	SeaSoar deployed but rope through wing handle knotted, took turns round bomb 
weight and tore it loose. Needed to bring into hangar to get at it. metal bracket bent. Metal 
cover needed cutting. Screw holes redrilled.
0553	Redeployed for SeaSoar Run 7


Fr 25.10.96
0312	Strong winds forced recovery of SeaSoar and CPR
0438	Hove to
1000	Return to SeaSoar break off point and try steaming along track.
1230	Redeploy to continue Run 7. Done by 1300. Only making 7 kn max but SeaSoar flying 
OK. Gradually improved as sea went down.
2100	Recover.
2156	CTD 12993 at 'X57.6'.
2200	Found that nontoxic supply to thermosalinograph and underway nutrient sensor had 
somehow been turned off. Also found thermosalinograph sensors had been inversely 
connected throughout cruise.

Sa 26.10.96
0030	Begin SeaSoar Run 8 on course 313 Deployment of CPR much eased by hydraulic 
ram connected to boom on port quarter.
1400	Recover SeaSoar for CTD on west side of Reykjanes Ridge.
1520	CTD 12994
1757	Redeploy SeaSoar to continue Run8.

Su 27.10.96
0657	Recovered SeaSoar in good conditions.
0824	CTD 12995 at W60, the first of 7 CTDs worked westward to Greenland shelf edge.
1117	First of 7 P-ALACE floats deployed.

Mo 28.10.96
0649	Begin 5th of CTDs, 12999. Found Level A not plugged in. Cast restarted at 0743.
0922	Begin run west across Greenland Shelf to examine current on the shelf.
1400	Alter course 090 for reverse run.
1535	Begin CTD 13000, westernmost of line.
1809	Begin last CTD 13001.
1953	Deploy SeaSoar for Run 9 south then southeast along Topex/Poseidon track. 

Tu 29.10.96
0600	Alter course 130
1546	CTD 13002 after recovering SeaSoar
1904	Begin SeaSoar Run 10 continuing SE towards W54 along T/P track.

We 30.10.96
1300	Cancelled CTD due in an hour just west of R Ridge because (1) weather marginal, risk 
of damaging gear to no great purpose, (2) CFC kit poor, needs long bakeout, (3) CTD cable 
leakage found, needs retermination, (4) if we run on, we may get to the other side of the 
weather front by tomorrow with better conditions, (5) and major scientific reason is that 
Knorr will occupy a section close to this one within a week, at much closer station spacing 
than we can achieve.

Th 31.10.96
0000	All clocks went berserk. Usual leap sec problem?
1015	Recovered SS at W54. Several minor problems.
1148	CTD 13003
1430	Last ALACE float deployed.
1504	Begin SeaSoar Run 11

Fr 01.11.96
1030	CTD 13004 at X54 after SeaSoar recovery.
1422	Begin SeaSoar Run 12.

Sa 02.11.96
1115	CTD 13005 at Y54 after SeaSoar recovery. After the cast, the wire was found to have 
a major kink in it a metre or two above the CTD. Not clear when it happened. Reterminated. 
Wind strengthened rapidly from 7 to 15 m/s in 3 h so
1440	SeaSoar deployed for Run 13 without repositioning ship.

Su 03.11.96
0958	CTD 13006 at Z54.
1430	SeaSoar deployed for Run 14 east across southern entrance to Rockall Trough.

Mo 04.11.96
0948	Turned southeast (140) towards Irish Shelf parallel to intended Topex/Poseidon 
return track. Rolling unpleasantly from swell from westerly winds. No letup to weather from 
lows to north and west of us.
1729	Alter course to south. 
1918	Ended turn to 320, the Topex/Poseidon line. This had to be done rapidly to avoid 
rolling and anticlockwise to keep the CTD on the lee side. The SeaSoar was held near the 
surface during the turn. However, vehicle refused to respond shortly after profiling was 
recommenced. Recovered in poor conditions, and found badly bent wing plate, so wire must 
have wrapped round it. Hove to overnight.

Tu 05.11.96
0736	Wind had dropped a lot and swell organised, so returned to CTD position at east side 
to Rockall Trough.
0845	CTD 13007.
1122	Not ready to deploy SeaSoar. Wing end plates being reprofiled so less likely to foul. 
Then found data needed by new SeaSoar control program had been deleted during backup 
operations.
1249	SeaSoar deployed for Run 15 across Rockall Trough following satellite track.
1600	Conditions untenable, rolling serious. Primary phosphate standard broke in the 
refrigerator. SeaSoar recovered OK though pitching flooded afterdeck several times.
1658	Hove to.

We 06.11.96
0000	Still hove to.
1939	Conditions eased enough to redeploy SeaSoar (Run 15 continued) and run a dogleg 
course, initially 280, to the CTD position on the west side of Rockall Trough. CPR cable 
kinked during deployment. Reterminated.

Th 07.11.96
0220	Alter course to 040.
0834	Recover SeaSoar at end of Run 15
0944	CTD 13008 on west side of Rockall Trough.
1156	SeaSoar redeployed for Run 16 northwest (316) across the southwest flanks of 
Rockall and Hatton Banks towards Z57.

Fr 08.11.96
1205	Recovered SeaSoar.
1310	CTD 13009 then 2 plankton nets, to 500m and 200m to look at daytime depth 
distribution.
1606	Ran east (081) without SeaSoar to do a second CTD at 20W.
1947	CTD 13010 on 1000m contour on western flank of Hatton Bank.
2102	SeaSoar deployed for Run 17 westward along 57N.

Sa 09.11.96
1708	CTD 13011 at Y57. Excellent weather but forecast to break so did not spend time 
repositioning ship before and after CTD.
1955	SeaSoar deployed for Run 18.

Su 10.11.96
0000	Working west all day but slowed by strong winds and developing swell.
1832	Passed position for next CTD but deferred it because conditions too bad. Speed 
reduced to 5-7 knots so SeaSoar reaching 350m but not surface. Needed a northwest course to 
complete large circuit via Greenland, but wind 310, so courses 280 and 330 either side of 
the wind preferred to gain a little speed. Speed 4-6 knots.

Mo 11.11.96
0649	Wind easing as we reached turning point. Shortened SeaSoar cable to allow quick turn.
0721	Steady on course 134. Paid out cable to full length again. Passage a great deal more 
pleasant with wind and swell behind and reducing.
1421	Recover SeaSoar. Found kinks in wire right at cowtail and 1m up, also bridle bent 
sideways. Reterminated. Light channel lead replaced also as channel was becoming noisy.
1614	CTD 13012 at Z57 after some delay. The multisampler was noisy and fired a bottle 
randomly while on deck. Connector remade.
1826	CTD and net finished. Hove to awaiting completion of SeaSoar repairs.
2034	SeaSoar deployed for Run 19 southeast along a Topex/Poseidon track, due to continue 
for some days.

Tu 12.11.96
1200	CTD 13013. Some noise noted on the cast, so cable reduced by 50 m and reterminated 
after it.
1557	SeaSoar deployed for Run 20, but not CPR, as running out of silks.

We 13.11.96
Long run through Y54. Ashtech locked at 0713, took until 0815 to fix, had to start it from 
scratch, so lost all settings. Around midnight reset to Brian King's defaults. Double net on 
today's cast.


Th 14.11.96
SS deployed after double net then CTD. About an hour before remembered to plug in the level 
A so no data until 1640 or so.

Fr 15.11.96
0744	Station 13107.
1039	Start SS Run 23

Sa 16.11.96
0805	Station 13018.
1157	Start SS Run 24

Su 17.11.96
0401	End SS Run 24.
0545	Station 13019.

Mo 18.11.96
Evening	Docked in Southampton.



8. ACKNOWLEDGEMENTS

The principal scientists would like to thank the Master, officers, crew and scientists of the RRS 
Discovery for making this such an enjoyable, as well as successful cruise.




TABLES

Table  1. CTD casts
Table  2. Main processing execs and file names
Table  3. Pressure sensor hysteresis correction
Table  4. CTD Salinities: calculated mean offsets, standard deviation, and linear offset applied
Table  5. Differences between CTD and reversing thermometer and pressure meter data.
Table  6. Phytoplankton Net Hauls
Table  7. SeaSoar Deployments
Table  8. SeaSoar Salinity Calibrations
Table  9. Fitting Parameters for SeaSoar Fluorometer Calibration
Table 10. P-ALACE Float Deployments
Table 11. Listing of deepctd.cal
Table 12. Listing of shalctd.cal
Table 13. ADCP Files
Table 14. Depth Files
Table 15. Salinity Differences
Table 16. Continuous Plankton Recorder Deployments
Table 17. Days and dates, 1996


FIGURES

Fig.1 Track chart

Fig.2 Vertical distribution of samples

Fig.3 GPS Scatter plots: (a) GPS in Falmouth, (b) DGPS in Falmouth, (c) DGPS in Reykjavik.

Fig.4 Salinity offset as a function of time

Fig.5 Bottle-CTD salinity residuals

Fig.6 Oxygen Calibration Parameters Alpha and Beta as a Function of Depth.

Fig.7 Difference between surface SeaSoar data and bottle salinity samples for 
      RRS Discovery Cruise 223.

Fig.8 Salinity differences of the Salinity Standards.

Fig.9 Meteorological conditions during RRS Discovery Cruise 223.




