      1.  CRUISE NARRATIVE: A16S
          (Last update: 2004.09.24)
      

      1.1  HIGHLIGHTS



                           WHP CRUISE SUMMARY INFORMATION

               WOCE section designation  A16S
      Expedition designation (EXPOCODE)  318MSAVE5
          Chief Scientists/affiliations  DR. WILLIAM A. SMETHIE / LDEO
                                         DR. MICHAEL MCCARTNEY/WHOI

                           Cruise dates  1989.JAN.23 - 1989.MAR.08
                                   Ship  R/V MELVILLE
                          Ports of call  Cape Town, South Africa to 
                                         Montevideo, Uruguay
                     Number of stations  73 CTD/Rosette (13 Large Volume)

                                                     3216.70' S
        Stations' geographic boundaries  5015.60' W             0059.10' E
                                                     5358.10' S
           Floats and drifters deployed  0
         Moorings deployed or recovered  0
        

                           CHIEF SCIENTISTS' CONTACT INFO.

             Dr. William A. Smethie  Lamont-Doherty Earth Observatory
                     Columbia University  Palisades  NY  10964
                     TEL: 914-359-2900 x566  FAX: 914-365-8157
                          EMAIL: bsmeth@ldeo.columbia.edu

         Dr. Michael McCartney  Dept. of Physical Oceanography, Clark 344
           Woods Hole Oceanographic Institution  Woods Hole  MA  02543
                       TEL: 508-289-2797  FAX: 508-457-2181
                             EMAIL: mike@gaff.whoi.edu




                       SOUTH ATLANTIC VENTILATION EXPERIMENT
                                       (SAVE)
                                       Leg 5
                                    R/V MELVILLE
                           23 January 1989 - 8 March 1989
                   Cape Town, South Africa to Montevideo, Uruguay

                              Data Report Prepared by:

                            Oceanographic Data Facility
                        Scripps Institution of Oceanography
                        University of California, San Diego

                                     April 1992

      
      Sponsored by

      National Science Foundation                        ODF Publication No. 232
      Grand OCE-86 13330                                     SIO Reference 92-10



      CHIEF SCIENTIST'S OVERVIEW
      
      Leg 5 of SAVE (denoted Hydros 3 by Scripps, and A16C for the WOCE project) 
      was carried out on the R/V Melville and was actually a combination of a 
      meridional section across the Argentine Basin at 41W and a short section 
      perpendicular to the western boundary at about 35S planned as part of 
      SAVE, and the southern end of a meridional. long line in the Atlantic 
      Ocean planned by M. McCartney, L. Talley and M. Tsuchiya that extended 
      from 32.5S, 25W to South Georgia Island
      
      The cruise departed from Cape Town on January 23,1989 at 1400. The first 
      station, a reoccupation of AJAX station 44 at 36S, 1E, was taken on 
      January 26. Work began on the 25W line on February I with station 237 
      taken at 3230' S, 2500' W. The southernmost station (278) just north 
      of South Georgia Island was taken on February 17. The station spacing 
      was about 30 na. mi. along this line. The section along 41W (stations 
      279-304) was occupied between February 18 and March 2 with a station 
      spacing of about 65 na. mi. The portion of the western boundary section 
      outside Uruguay's 200 mile zone (stations 305-308) was taken between 
      March 4 and March 6. Stations inside Uruguay's 200 mile zone were taken 
      on the following leg when an Uruguayan observer was on board. The cruise 
      ended in Montevideo on March 8, one day later than scheduled. The one 
      day delay was caused by a breakdown of the main engine, which was 
      repaired at sea.
      
      The total number of miles steamed was 5989 and the total number of CTD-
      rosette stations occupied was 73. These stations were taken using a Neil 
      Brown CTD interfaced to a Scripps Ocean Data Facility rosette equipped 
      with thirty-six 10 liter bottles. At 13 of the stations large volume 
      samples were collected using Gerard barrels. Generally 18 large volume 
      samples were collected between the surface and the bottom. The total 
      steaming time for the cruise was 25 days, 15 hours and the total station 
      time was 17 days, 5 hours. Originally, 81 stations had been planned, but 
      8 stations were dropped because of time lost during rough weather. 
      Approximately 1.25 days were lost because of slow steaming and greater 
      time required to complete casts in rough weather and an equal amount of 
      time us lost because of equipment failures during rough weather. Most of 
      the equipment failures were Gerard barrels not tripping properly and 
      breaks in the CTD termination.1. 

      
      
      LIST OF PARTICIPANTS
      
      Ship's Captain     | Curtis D. Johnson       | Scripps Institution of 
                         |                         |   Oceanography
      -------------------|-------------------------|--------------------------
      Chief Scientist    | William M. Smethie, Jr. | Lamont-Doherty Geological 
                         |                         |   Observatory
      -------------------|-------------------------|--------------------------
      Co-chief Scientist | Michael S. McCartney    | Woods Hole Oceanographic 
                         |                         |   Institution

      
      IFREMER, Brest, France                   Kevin G. Speer

      Lamont-Doherty Geological Observatory    Michael T. Benjamin
                                               Richard P. Cember 
                                               Mieczyslawa Klas 
                                               Kathy A. Tedesco

      Massachusetts Institute of Technology    Stephen G. Zemba

      Physics Institute of Bern, Switzerland   Jose M. Rodriguez

      Princeton University                     Richard J. Rotter

      Scripps Institution of Oceanography/ODF  David L. Bos 
                                               Carol Conway 
                                               Frank M. Delahoyde 
                                               Arthur W. Hester 
                                               John K. Jain 
                                               Leonard T. Lopez 
                                               Douglas Masten 
                                               David A. Muus

      Scripps Institution of Oceanography      George H. Bouchard 
                                               Ronald L. Comer 
                                               Frederick A. Van Woy

      Texas A&M University                     Bret B. Bergland

      Woods Hole Oceanographic Institution     Danuta Kaminski 
                                               Jan C. Zemba
                                                     



      Leg      | STATIONS  |      DEPARTURE          |      ARRIVAL
      ---------|-----------|-------------------------|------------------------
      SAVE 1   |   1 - 43  | Recife, Brazil          | Abidjan, Ivory Coast
               |           |   23 November 1987      |   13 December 1987
      ---------|-----------|-------------------------|------------------------
      SAVE 2   |  44 - 105 | Abidjan, Ivory Coast    | Rio de Janeiro, Brazil
               |           |   18 December 1987      |   23 January 1988
      ---------|-----------|-------------------------|------------------------
      SAVE 3   | 106 - 170 | Rio de Janeiro, Brazil  | Abidjan, Ivory Coast
               |           |   29 January 1988       |   07 March 1988
      ---------|-----------|-------------------------|------------------------
      SAVE 4   | 171 - 235 | Punta Arenas, Chile     | Cape Town, South Africa
               |           |   07 December 1988      |   15 January 1989
      ---------|-----------|-------------------------|------------------------
      SAVE 5   | 236 - 308 | Cape Town, South Africa | Montevideo, Uruguay
               |           |   23 January 1989       |   08 March 1989
      ---------|-----------|-------------------------|------------------------
      HYDROS-4 | 309 - 379 | Montevideo, Uruguay     | Bridgetown, Barbados
               |           |   13 March 1989         |   19 April 1989
      
      
      

      INTRODUCTION  
      
      The broad objectives of the South Atlantic Ventilation Experiment (SAVE) 
      are to investigate the rates of ocean circulation, mixing, ventilation, 
      inter-ocean exchange, and carbon, oxygen and nutrient cycling on an 
      ocean basin scale. Transient and radioactive tracers are well suited for 
      pursuing these objectives because they integrate over various spatial 
      and temporal scales, providing strong constraints on time-averaged rates 
      of circulation and mixing, and revealing pathways between the air/sea 
      interface and the abyssal ocean that are not always discernible from 
      traditional hydrographic and nutrient observations. The results should 
      lead to a better understanding of the ocean's major role in the earth's 
      climate, via its control of the global heat and carbon dioxide budgets.
      
      The specific problems that will be addressed include:
      
      1) Exchange of South Atlantic waters with the North Atlantic, Pacific, 
         Antarctic and Indian Oceans,
      2) Formation and spreading rates of intermediate waters,
      3) Thermocline ventilation rates and locations,
      4) Rates of biologically-mediated metabolic processes,
      5) Diapycnic processes,
      6) Origins of deep and bottom waters and their spreading routes and 
         rates.

      Underway/XBT Program

      XBT casts were usually taken between CTD stations. Where the station 
      spacing was 30nm, one XBT was taken and for greater spacing 2 XBTs were 
      taken. The XBT casts were accompanied by water samples for dissolved 
      oxygen, pCO2, salinity and nutrients taken from the Melville's clean 
      seawater line.

      Bathymetry

      Depth was measured continuously along the entire cruise track using a 
      12KHz precision depth recorder. The raw data was digitized by hand at 5-
      minute intervals and a tape of the reduced data will be produced by the 
      Geological Data Center at Scripps.


                         A16S (SAVE 5)  Smethie/McCartney  R/V Melville  1989
      __________________________________________________________________________
      __________________________________________________________________________


      2.  BOTTLE DATA COLLECTION, ANALYSES, AND PROCESSING
      
      ODF CTD/rosette casts were carried out with a 36-bottle rosette sampler 
      of ODF manufacture using a General Oceanics pylon. An ODF-modified NBIS 
      Mark 3 CTD and a SeaTech transmissometer provided by Texas A&M 
      University (TAMU) were mounted on the rosette frame. Seawater samples 
      were collected in 10-liter PVC Niskin bottles mounted on the rosette 
      frame. These bottles were numbered 1 through 36, if one of these 36 
      bottles needed servicing and repairs could not be accomplished by the 
      next cast, the replacement bottle was numbered 71-78. Added CTD levels, 
      no water samples, were assigned bottle numbers 95-99. Subsets of CTD 
      data taken at the time of water sample collection (a 10 second average) 
      were transmitted to the bottle data files immediately after each cast to 
      provide pressure and temperature at the sampling depth, and to 
      facilitate the examination and quality control of the bottle data as the 
      laboratory analyses were completed.
      
      After each rosette cast was brought on board, water samples were drawn 
      in the following order: Freon, Helium-3, Oxygen, Oxygen-18, pCO2. CO2, 
      Tritium, Nutrients, Salinity and Suspended Particulate Matter. Other 
      ancillary program samples were drawn after the core samples. The samples 
      and the Niskin sampler they were drawn from were recorded on the Sample 
      Log sheet. Comments regarding validity of the water sample (valve open, 
      lanyard caught in lid, etc.) were also noted on the Sample Log sheets.
      
      Table 1 is a tabulation of samples collected during all six legs [SAVE 
      Legs 1 through 5 (STS/ODF, 1992) and HYDROS Leg 4 (STS/ODF, 1992)] 
      unless otherwise noted and includes the Principal Investigators and 
      their institutions. Samples collected on each station are tabulated in 
      the Station and Cast Description.
      
      Gerard casts were carried out with -270 liter stainless steel Gerard 
      barrels on which were mounted 2-liter Niskin bottles with reversing 
      thermometers. Samples for salinity, 14C, 228Ra, 39Ar, and 85Kr Were 
      obtained from the Gerard barrels. The Gerard barrels were numbered 81 
      through 91 and the piggy-back Niskin were numbered 41 through 70. 
      Surface samples taken from the ship's underway pump line were assigned a 
      bottle number of 98 through 99. Salinity check samples were always drawn 
      from the Niskin bottles for comparison with the Gerard barrel salinities 
      to try to verify the integrity of the Gerard sample. Occasionally, 
      barium and some of the samples normally taken from the rosette were also 
      drawn from the Gerard-mounted Niskin bottle. These were also recorded on 
      a Sample Log sheet.
      
      The discrete hydrographic data were entered into the shipboard data 
      system and processed as the analyses were completed. The bottle data 
      were brought to a useable, though perhaps not final, state at sea. ODF 
      data checking procedures included verification that the sample was 
      assigned to the correct level. This was accomplished by checking the raw 
      data sheets, which included the raw data value and the water sample 
      bottle, versus the sample log sheets. Any comments regarding the water 
      samples were investigated. The raw data computer files were also checked 
      for entry errors. Investigation of data included comparison of bottle 
      salinity and oxygen with CTD data, and review of data plots of the 
      station profile alone and compared to nearby stations.
      
      If a data value did not either agree satisfactorily with the CTD or with 
      other nearby data, then analyst and sampling notes, plots, and nearby 
      data were reviewed. If any problem was indicated the data value was 
      flagged or deleted. (However, ODF preserves in its archives all bottle 
      data values). The Bottle Data Processing Notes section includes comments 
      regarding deletion of samples.
      
      If it was determined that an entire 10 liter water sample was 
      contaminated by leakage or other bottle or rosette malfunction, the 
      level is reported with just the CTD data (pressure, temperature and 
      salinity). This has been done to preserve the profile and accommodate 
      investigators who prefer using bottle data files exclusively.
      

                                # Of   ||                        # Of 
             Parameter         Samples || Parameter             Samples
             ----------------- ------- || --------------------- -------
             discrete salinity  3179   || pCO2                   845
             discrete temp.      546   || suspended part.        369
             oxygen             2530   || Keeling C02 Neodynium   20
             nutrients          2517   || Barium                 280
             CFMs               1592   || 14C                    187
             Helium-3            346   || Ra-228                 237
             Tritium             346   || Kr-85                   87
             TCO2               1040   || Ar-39                   13


      2.1. PRESSURE AND TEMPERATURES
      
      All pressures and temperatures for the Niskin bottle data tabulations on 
      the rosette casts were extracted from the processed CTD data, usually 
      those from the corrected 10-second average bottle trip files collected 
      during the up cast (see CTD DATA COLLECTION, ANALYSES, AND PROCESSING).
      
      Gerard pressures and temperatures were calculated from Deep-Sea 
      Reversing Thermometer (DSRT) readings. Each DSRT rack normally held 2 
      protected (temperature) thermometers and I unprotected (pressure) 
      thermometer. Thermometers were read by two people, each attempting to 
      read a precision equal to one tenth of the thermometer etching interval. 
      Thus, a thermometer etched at 0.05 degree intervals would be read to the 
      nearest 0.005 degrees. Each temperature value is therefore calculated 
      from the average of four readings.

          IT SHOULD BE CLEARLY NOTED THAT THE TEMPERATURES PRODUCED AND 
          PUBLISHED BY ODF IN THIS REPORT ARE BASED ON THE INTERNATIONAL 
          PRACTICAL TEMPERATURE SCALE OF 1968, RATHER THAN THE CURRENTLY 
          USED INTERNATIONAL TEMPERATURE SCALE OF 1990. 
                (The expedition took place before I January 1990, 
                          the starting date for ITS-90).
      

      2.2. SALINITY
      
      Salinity samples were drawn into ODF citrate salinity bottles which were 
      rinsed three times before filling. Salinity was determined after sample 
      equilibration to laboratory temperature, usually within about 8-36 hours 
      of collection. Salinity has been calculated according to the equations 
      of the Practical Salinity Scale of 1978 (UNESCO, 198 1) from the 
      conductivity ratio determined from bottle samples analyzed (minimum of 
      two recorded analyses per sample bottle after flushing) with a Guildline 
      Autosal Model 8400A salinometer standardized against Wormley P- 108 
      standard seawater, with at least one fresh vial opened per cast, or from 
      the corrected CTD conductivity, temperature, and pressure.
      
      Accuracy estimates of bottle salinities run at sea are usually better 
      than 0.002 psu relative to the specified batch of standard. Although 
      laboratory precision of the Autosal can be as small as 0.0002 psu when 
      running replicate samples under ideal conditions, at sea the expected 
      precision is about 0.001 psu under normal conditions, with a stable lab 
      temperature. Still, because a small droplet of fresh water, or the 
      residue from a small evaporated droplet of seawater, can affect a bottle 
      salinity in the third decimal place, and because the Autosal salinometer 
      is sensitive to environmental fluctuations, salinities from bottle 
      samples have a lower true precision under field conditions than in the 
      laboratory. ODF typically deleted the Niskin bottle salinity from this 
      report, and substituted the corrected CTD salinity, whenever there was 
      any question regarding its validity (see BOTTLE DATA PROCESSING NOTES).
      

      2.3. OXYGEN
      
      Samples were collected for dissolved oxygen analyses soon after the 
      rosette sampler was brought on board and after CFC and Helium were 
      drawn. Nominal 100 ml volume iodine flasks were rinsed carefully with 
      minimal agitation, then filled via a drawing tube, and allowed to 
      overflow for at least 2 flask volumes. Reagents were added to fix the 
      oxygen before stoppering. The flasks were shaken twice; immediately, and 
      after 20 minutes, to assure thorough dispersion of the Mn(OH)2 
      precipitate. The samples were analyzed within 4-36 hours.
      
      Dissolved oxygen samples were titrated in the volume-calibrated iodine 
      flasks with a I ml microburet, using the whole-bottle Winkler titration 
      following the technique of Carpenter (1965). Standardizations were 
      performed with 0.01N potassium iodate solutions prepared from pre-
      weighed potassium iodate crystals. Standards were run at the beginning 
      of each session of analyses, which typically included from I to 3 
      stations. Several standards were made up and compared to assure that the 
      results were reproducible, and to preclude basing the entire cruise on 
      one standard, with the possibility of a weighing error. A correction (-
      0.014 ml/l) was made for the amount of oxygen added with the reagents. 
      Combined reagent/seawater blanks were determined to account for 
      oxidizing or reducing materials in the reagents, and for a nominal level 
      of natural iodate (Brewer and Wong, 1974) or other oxidizers/reducers in 
      the seawater.
      
      The assay of the finest quality K103 available to ODF is 100%, 0.05%, 
      but the true limit in the quality of the bottle oxygen data lies in the 
      practical limitations of the present sampling and analytical 
      methodology, from the time the rosette bottle is closed through the 
      calculation of oxygen concentration from titration data. Overall 
      precision within a group of samples has been determined from replicates 
      on numerous occasions, and for the system as employed on this 
      expedition, one may expect 0.1 to 0.2%. The overall accuracy of the 
      data is estimated to be 0.5%.
      
      
      TABLE 1: SCIENTIFIC PROGRAMS
      
      Participating | Principal                   | Scientific          |
      Institutions  | Investigators               | Programs            | Leg
      --------------|-----------------------------|---------------------|----
      STS/ODF       | Mr. David Wirth             | Salinity            | ALL
                    |                             | Oxygen              | ALL
                    |                             | Nitrate, Nitrite,   | ALL
                    |                             | Phosphate, Silicate | ALL
                    |                             | CTD Profiles        | ALL
      --------------|-----------------------------|---------------------|----
      LDGO          | Dr. Wallace S. Broecker     | Carbon-14           | ALL
      MIAMI         | Dr. H. Gte Ostlund         |                     |
      MIAMI         | Dr. Zafer Top               |                     |
      --------------|-----------------------------|---------------------|----
      WHOI          | Dr. William J. Jenkins      | Helium-3            | ALL
                    |                             | Tritium             | ALL
      --------------|-----------------------------|---------------------|----
      PRINCE        | Dr. Jorge L. Sarmiento      | Radium-228          | ALL
      PRINCE        | Dr. Robert M. Key           | Radium-226          | ALL
      SIO           | Dr. Ray F. Weiss            | Freon-11            | ALL
      LDGO          | Dr. William M. Smethie, Jr. | Freon-12            | ALL
      LDGO          | Dr. William M. Smethie, Jr. | Krypton-85          | ALL
      --------------|-----------------------------|---------------------|----
      BERN          | Dr. Heinz Loosli            | Argon-39            | ALL
      LDGO          | Dr. William M. Smethie, Jr. |                     |
      BERN          | Dr. J. H. Oeschger          |                     |
      --------------|-----------------------------|---------------------|----
      LDGO          | Dr. Taro Takahashi          | Total CO2           | ALL
                    |                             | pCO2                |
      --------------|-----------------------------|---------------------|---
      LDGO          | Dr. Arnold Gordon           | XBT Profiles        | ALL
      LDGO          | Mr. Stanley Jacobs          |                     |
                     
      
      ANCILLARY PROGRAMS
                     
      Participating | Principal              | Scientific  
      Institutions  | Investigators          | Programs                         | Leg
      --------------|------------------------|----------------------------------|-----
      TAMU          | Dr. Wifford Gardner    | Suspended Particulate Matter     | ALL
                    |                        | Transmissometer                  | ALL
      --------------|------------------------|----------------------------------|-----
      SIO           | Dr. Charles D. Keeling | Total CO2                        | ALL
      SIO/GDC       | Mr. Stuart M. Smith    | Bathymetry                       | ALL
      LDGO          | Dr. James K. B. Bishop | Barium                           | ALL
      --------------|------------------------|----------------------------------|-----
      SIO           | Dr. Ray F. Weiss       | Underway pN20, pCO2, pCH4        | ALL
                    |                        | Underway Surface Measurements    | ALL
      --------------|------------------------|----------------------------------|-----
      LDGO          | Dr. Andrew McIntyre    | Coccolith                        |  1
      URI           | Dr. Michael Bender     | Oxygen-18                        |  2
      LDGO          | Dr. K. K. Liu          | Nitrogen-15                      |  2
      --------------|------------------------|----------------------------------|-----
      UH            | Dr. Chris Measures     | Beryllium Isotopes               |  3
                    |                        | Aluminum                         |  3
      --------------|------------------------|----------------------------------|-----
      CNES/GRGS     | Dr. Catherine Jeandel  | Neodymium                        |4 & 5
      SIO           | Dr. Martin Whelen      | 13C, 14C in methane (air samples)|  5
      
      
      INSTITUTION CODES:
      -----------------------------------------------------------------------
      BERN       Physics Institute of Bern, Switzerland
      CNES/GRGS  Observatorie of Midi-pyrenees, Toulouse, France
      LDGO       Lamont-Doherty Geological Observatory of Columbia University
      MIAMI      University of Miami
      PRINCE     Princeton University
      SIO        Scripps Institution of Oceanography
      SIO/GDC    Scripps Institution of Oceanography/Geological Data Center
      STS/ODF    Shipboard Technical Support/Oceanographic Data Facility
      TAMU       Texas A & M
      UH         University of Hawaii
      URI        University of Rhode Island
      WHOI       Woods Hole Oceanographic Institution
      
      
      Oxygens were converted from milliliters per liter to micromoles per 
      kilogram using the equation:

             O2[m/kg]=O2[ml/l]/(.022392*(1.0+sigma theta/1000.0))
      
      The potential density anomaly, sigma theta, is the potential density in 
      kg/m3 referenced to pressure=0, from which 1000 has been subtracted.
      

      2.4. NUTRIENTS
      
      Nutrients (phosphate, silicate, nitrate and nitrite) analyses, reported 
      in micromoles/kilogram, were performed on a Technicon AutoAnalyzer(r). 
      The procedures used are described in Hager et al. (1972) and Atlas et 
      al. (1971). Standardizations were performed with solutions prepared 
      aboard ship from pre-weighed standards; these solutions were used as 
      working standards before and after each cast (approximately 36 samples) 
      to correct for instrumental drift during analyses. Sets of 4-6 different 
      concentrations of shipboard standards were analyzed periodically to 
      determine the linearity of colorimeter response and the resulting 
      correction factors. Phosphate was analyzed using hydrazine reduction of 
      phosphomolybdic acid as described by Bernhardt & Wilhelms (1967). 
      Silicate was analyzed using stannous chloride reduction of 
      silicomolybdic acid. Nitrite was analyzed using diazotization and 
      coupling to form dye; nitrate was reduced by copperized cadmium and then 
      analyzed as nitrite. These three analyses use the methods of Armstrong 
      et al. (1967).
      
      Sampling for nutrients followed that for the tracer gases, CFCs, He, 
      Tritium, and dissolved oxygen. Samples were drawn into -45 cc high 
      density polyethylene, narrow mouth, screw-capped bottles which were 
      rinsed twice before filling. The samples may have been refrigerated at 2 
      to 6C for a maximum of 15 hours.
      
      Nutrients were converted from micromoles per liter to micromoles per 
      kilogram by dividing by sample density calculated at an assumed 
      laboratory temperature of 25C.


                         A16S (SAVE 5)  Smethie/McCartney  R/V Melville  1989
      __________________________________________________________________________
      __________________________________________________________________________


      3. CTD DATA COLLECTION, ANALYSES, AND PROCESSING
      
      Year-2 of SAVE (Legs 4 and 5) were processed with Hydros-4 therefore 
      there may be references made to Hydros-4. 209 CTD casts were completed 
      using a 36-bottle rosette sampling system; 64 casts were completed on 
      Save Leg 4, 74 on Save Leg 5 one of which was a test and not reported in 
      this report, and 71 casts on Hydros-4. STS/ODF CTDs #1 and #2, modified 
      NBIS Mark IIl-B instruments, were both used during SAVE-4; CTD-1 was 
      used exclusively on SAVE-5 and Hydros-4. The CTD data were initially 
      processed into a filtered, half-second average time-series during the 
      data acquisition. The pressure and PRT temperature channels were 
      corrected using laboratory calibrations. The conductivity/salinity 
      channels were calibrated to salinity check samples acquired on each 
      cast. The CTD time-series data were then pressure-sequenced into 2-
      decibar pressure intervals, and the pressure series oxygen channel was 
      corrected to match oxygen check samples acquired on each upcast.
      

      3.1. CTD LABORATORY CALIBRATIONS
      3.1.1. PRESSURE TRANSDUCER CALIBRATION
      
      Each CTD pressure transducer was calibrated in a temperature-controlled 
      bath by comparison with pressures generated by a Ruska Model 2400 piston 
      gage. The mechanical hysteresis loading and unloading curves were 
      measured both pre- and post-cruise at cold temperature (-I to 0.5C 
      bath) to a maximum of 8830 psi, and at warm temperature (28-30C bath) 
      to a maximum of 2030 psi.
      
      3.1.2. PRT TEMPERATURE CALIBRATION
      
      The CTD-1 and all CTD-2 PRT temperature sensors were calibrated in a 
      temperature-controlled bath by comparison with temperatures calculated 
      from the resistance of a Rosemount Model 162CE standard platinum 
      thermometer, measured by a NBIS model ATB 1250 resistance bridge. The 
      Rosemount standard PRT was checked periodically in water and diphenyl 
      ether triple-point cells. Seven or more calibration temperatures, spaced 
      across the range of 0 to 30C, were measured both pre- and post-cruise. 
      The CTD-2 primary PRT temperature transducer was replaced after SAVE-4, 
      station 185, so the pre- and post-cruise calibrations for that 
      temperature channel are not comparable.
      
      
      3.2. CTD DATA PROCESSING
      3.2.1. CTD DATA ACQUISITION
      
      Eight data channels (pressure, temperature, second temperature, 
      conductivity, dissolved oxygen, transmissometer, altimeter and elapsed 
      time) were acquired by CTD-2 at a data rate of 25 Hz. CTD-1 acquired 
      seven cbannels, having only one temperature transducer. The FSK CTD 
      signal was demodulated by an STS/ODF-designed deck unit and output to an 
      RS-232 bus interface. An Integrated Solutions, Inc. (ISI) Optimum V 
      computer served as the real-time data acquisition processor.
      
      Data acquisition consisted of storing all raw binary data on hard disk, 
      then on magnetic cartridge tape, and generating a corrected and filtered 
      half-second average time-series. Data calculated from this time series 
      were reported and plotted during the cast. A 10-second average of the 
      time-series data was calculated for each water sample collected during 
      the data acquisition.
      
      Generating the half-second time-series data set involved applying 
      single-frame absolute value and gradient filters, then performing a two-
      pass 4,2 standard-deviation data rejection to all channels. During the 
      acquisition, the pre-cruise laboratory calibration data were applied to 
      pressure and temperature. Pressure, conductivity and oxygen were matched 
      to the thermal response of the PRT temperature transducer. This lag time 
      was determined using raw CTD data from the cruise. The conductivity and 
      oxygen channels were corrected for thermal and pressure effects.
      
      3.2.2. PRESSURE, TEMPERATURE AND CONDUCTIVITY/SALINITY CORRECTIONS
      
      A maximum of 36 salinity and oxygen check samples, plus 4 thermometric 
      pressure and temperature measurements, were collected during each CTD 
      cast. A 10-second average of the CTD time-series data was calculated for 
      each trip time sample. The resulting data were then used to verify the 
      pre- and post-cruise pressure and temperature calibrations, and to 
      derive CTD conductivity/salinity and oxygen corrections.
      
      3.2.2.1. CTD PRESSURE CORRECTIONS
      3.2.2.1.1. CTD #2

      The pre- and post-cruise pressure calibrations were compared. The 
      warm/shallow calibration curve shifted by almost 3 decibars from pre- to 
      post-cruise, and the cold/deep calibration curve shifted by 3.5 
      decibars. There were no notable slope differences between the two sets 
      of calibrations. Offsets are adjusted automatically for each station as 
      the CTD enters the water, so there were no significant differences 
      between the two calibration results for CTD-2.
      
      Since all CTD-2 casts were done during the first of the three Hydros 
      legs, closer to the pre-cruise calibrations, no change was made to the 
      shipboard CTD-2 pressure data, to which the pre-cruise pressure 
      calibrations had already been applied. Thermometric pressures collected 
      during the CTD-2 casts were minimal because of numerous lanyard hangups 
      or other problems. The few acceptable check-pressure differences gave no 
      indication of any problems with the CTD-2 calibrated pressures.
      
      3.2.2.1.2. CTD #1

      The laboratory calibration for CTD-1 at the end of Hydros-4 disclosed a 
      pressure problem affecting all three Hydros (SAVE/Year-2) legs:
      
      a.  Although pre- and post-cruise pressure calibrations matched (to 
          within 0.2 decibars) below 1190 decibars, the 0-decibar calibration 
          point differed by 2.5 decibars (loading) and 3 decibars (unloading) 
          between pre- and post-cruise.
      b.  There was a sudden 6-decibar jump in pressure response between the 
          1050- and 1190-decibar calibration points on the loading curve during 
          the post-cruise calibration.
      c.  The jump does not appear in the unloading curve, but shallower than 
          the 1400-decibar point, the post-cruise begins to deviate from the 
          pre-cruise calibration to a maximum of 3 decibars at the 0-decibar 
          calibration point.
      d.  The post-cruise pressure calibration was repeated, giving similar 
          results.
      
      The pre-cruise calibrations were re-checked, and a smaller/shallower 
      indication of the same problem could be seen on the cold loading curve 
      at 365 decibars. CTD-1 downcasts from all three legs of the cruise were 
      checked for sudden pressure shifts between 800 and 1600 decibars.
      
      The CTD-1 half-second time-series downcasts were checked for a ratio of 
      pressure difference to time difference ("r") greater than 2.5 
      (equivalent to a winch speed of 150 m/min). For each station with a 
      sudden pressure shift visible on Pressure vs. Time plots, there was 
      exactly one area where r was between 4 and 13. All but six of the jumps 
      occurred between 1000 and 1550 decibars, where the temperature ranged 
      from about 2.5 to 4C. The other six jumps, between 900 and 1000 
      decibars, occurred during casts at the beginning of SAVE-4 and at the 
      end of Hydros-4 All detectable rapid changes in pressure occurred in 0.6 
      to 1.5 seconds and were 1.5 to 10.2 decibars in magnitude.
      
      95 out of 192 CTD-1 casts were affected by a pressure jump as described 
      above. There were problems on many sequential casts, then no detectable 
      problem for many more casts in a row. The pressure at which the jump 
      occurred, and the magnitude of the jump, seemed to be random: there was 
      no apparent correlation to water temperature or elapsed time from the 
      cruise start.
      
      A "baseline" pressure correction curve was generated by averaging the 
      pre- and post-cruise calibration curves for each of the shallow/warm and 
      deep/cold data sets, then removing the 500- to 1500-decibar distortion 
      of the post-cruise calibrations by using the shape of the more typical 
      pre-cruise curve. This averaged out the surface differences and 
      maintained the deep consistency in the calibrations. This average 
      correction curve was used for all casts in which no pressure problem was 
      detected.
      
      Customized pressure corrections were generated for problem casts, as 
      identified by areas of r greater than 3.5. The "baseline" curve 
      described in the previous paragraph was used as the starting point for 
      each cast. The "average" curve was used from the surface to 365 decibars 
      and from the post-"jump" pressure to the bottom. The correction for the 
      beginning pressure of the jump was the post-jump correction value plus 
      the jump size, minus the real pressure change occurring in that time. A 
      straight-line correction was used between 365 decibars down and the 
      beginning pressure of the jump on the cold curve.
      
      The average upcast calibration curves were retained for each cast unless 
      the last corrected in-water surface pressure of an upcast was less than 
      -0.6 decibars. In these cases, the upcast correction curve was adjusted 
      by 0 at 365 decibars to a maximum of +1.5 decibars at the surface, which 
      allowed the curve to resemble the shape of the pre-cruise curve in cases 
      where the end-pressure warranted it.
      
      The corrections applied were intended to correct the distorted pressures 
      to within 2 decibars to maintain the WOCE CTD salinity standards. It 
      should be noted that other problems may still exist, but are not 
      detectable at this time. CTD-1 pressure data above 1600 decibars should 
      not be considered accurate to better than 2 decibars, while deeper data 
      should be within more typical error ranges.
      
      Thermometric pressures collected during the casts were compared with 
      CTD- 1 corrected pressure data. Any differences between the two sets of 
      pressures appeared to be rack-dependent.
      
      3.2.2.2. CTD TEMPERATURE CORRECTIONS
      3.2.2.2.1. CTD #2
      
      CTD-2 had two PRTs. PRT-1 was the main temperature sensor and began 
      drifting during station 177, seven stations into SAVE-4. The drifting 
      increased by stations 183-185, where it was finally isolated as a 
      temperature problem rather than a conductivity problem. PRT-2 was a 
      secondary temperature sensor installed to provide a check for the 
      primary PRT; it was used as the primary PRT for stations 177-185 and 
      210. PRT-2 was not located as near to the conductivity sensor as PRT-1 
      and therefore generated noisier CTD salinity data, as it was measuring 
      slightly different water and could not be matched properly to the 
      conductivity sensor response. CTD-2 was used for all stations from 171-
      185, plus 210 and 218: CTD-2 was re-installed at these last two stations 
      to test the new PRT-1 sensor, to ensure that CTD-2 could be used as a 
      backup if CTD-1 failed later in the expedition.
      
      The pre- and post-cruise laboratory temperature transducer calibrations 
      for PRT-1 were not comparable because a new sensor was installed during 
      SAVE-4 PRT-1a and PRT-2 data from the pre-cruise laboratory calibration 
      and from shipboard casts were compared to see if the relative difference 
      between them changed. There was good agreement between these two CTD-2 
      PRTs, the differences being consistent at calibration, within a given 
      station, and from station to station. No shift in either sensor occurred 
      until station 176, when the difference increased by .002. Since PRT- la 
      began shifting noticeably in the same direction during station 177, an 
      additional +.002 temperature offset was applied to station 176 data, 
      assuming some change may have begun at that time.
      
      A new sensor (PRT-1b) was installed in CTD-2 after station 185. The CTD 
      was used/tested during station 210, where PRT-1b also displayed a 
      drifting problem. CTD-2 was worked on again, then tested at station 218:
      
      PRT-1b functioned normally and was used as the CTD-1 primary PRT for 
      that cast. PRT-1b and PRT-2 differences from station 218 and the post-
      cruise calibration were compared. The post-cruise difference was an 
      average -.022 compared to the station 218 difference. PRT-2 shifted by 
      -.013 from pre-cruise to post-cruise laboratory calibrations, which 
      points to a -.035 shift in PRT-1b between station 218 and the post-
      cruise calibration. Two deep thermometric temperatures from station 218 
      also support this shift. The post-cruise PRT-1b laboratory calibration 
      curve, with an additional -.035 offset, was applied to station 218 CTD 
      temperature data.
      
      A comparison of the pre- and post-cruise laboratory CTD-2/PRT-2 
      temperature transducer calibrations showed an average -.013C shift for 
      PRT-2. There was also a small slope difference between the two PRT-2 
      calibrations. Since CTD-2 was used mostly at the beginning of the 
      expedition and there is no evidence to show that PRT-2 shifted by the 
      last cast it was used for, the pre-cruise PRT-2 laboratory temperature 
      calibration was applied to stations 177-185 and 210 CTD data.
      
      The few thermometric temperature differences available for comparison 
      with CTD-2 data support the temperature corrections used. Additional 
      verification of the temperature corrections was obtained by comparing 
      bottle salinity differences vs. CTD values generated from corrected 
      pressure and temperature, plus raw conductivity. There were no sudden 
      shifts in preliminary salinity differences on casts where a different 
      primary PRT was used or when temperature corrections were offset from 
      the laboratory calibrations.
      
      3.2.2.2.2. CTD #1
      
      CTD-1 had a single temperature sensor and was used for stations 186 
      through 379, except stations 210 and 218. A comparison of the pre- and 
      post-cruise laboratory CTD-1 PRT temperature transducer calibrations 
      showed a shift varying from -.001C at cold temperatures to -.0017 at 
      warm temperatures. An average of the two laboratory calibrations was 
      applied to the CTD-1 temperature data.
      
      Thermometric temperature data from the cruise were compared to the 
      calibrated CTD-1 temperature data. Any offsets in the differences tended 
      to correlate with thermometer rack number, no shifts in CTD-1 
      temperature data could be detected over the course of the cruise.
      
      3.2.2.3. CTD CONDUCTIVITY CORRECTIONS
      3.2.2.3.1. CTD #2

      Check-sample conductivities were calculated from the bottle salinities 
      using CTD-2 pressures and temperatures. The differences between sample 
      and CTD conductivities at all pressures were fit to CTD conductivity 
      using a linear least-squares fit. A conductivity correction slope was 
      not warranted at that time.
      
      Conductivity differences were then calculated: offsets were determined 
      for each cast and fit to station number. Preliminary offsets were 
      applied to stations 171 through 175 individually, based on conductivity 
      differences at pressures below 100 decibars. Stations 176-185 
      conductivity differences below 1000 decibars were re-fit, and smoothed 
      offsets were applied to those casts. Stations 210 and 218 conductivity 
      offsets were determined individually based on differences below 1000 
      decibars. The offsets were manually adjusted to account for 
      discontinuous shifts in the conductivity transducer response, or to 
      insure a consistent deep theta-S relationship from station to station.
      
      After applying the conductivity offsets, the need for a conductivity 
      slope as a function of conductivity was reevaluated: no slope was 
      required.
      
      3.2.2.3.2. CTD #1
      
      Check-sample conductivities were calculated from the bottle salinities 
      using CTD pressures and temperatures. The differences between sample and 
      CTD-1 conductivities at all pressures were fit to CTD conductivity using 
      a linear least-squares fit. Values greater than 2 standard deviations 
      from the fit were rejected. The resulting conductivity correction slope 
      was applied to each CTD-1 cast.
      
      Conductivity differences were calculated for each cast after applying 
      the preliminary conductivity slope correction. Residual conductivity 
      offsets were then computed for each cast and fit to station number. 
      Smoothed offsets were determined in three groups: stations 186-189 
      (first-order fit), stations 190-202 (0-order/same offset for all casts) 
      and stations 203-379 (0-order/same offset for all casts). The resulting 
      smoothed offsets were then applied to the data, then conductivity slope 
      as a function of conductivity was re-checked: no change was warranted. 
      Some offsets were manually adjusted to account for discontinuous shifts 
      in the conductivity transducer response, or to insure a consistent deep 
      theta-S relationship from station to station.
      
      It was noted that stations 190-202 had numerous casts of inconsistent 
      bottle data values caused by a scum buildup in the Autosal cell. Adding 
      to this problem were CTD-1 conductivity offsetting problems caused by 
      sensor fouling on stations 192 and 202. The Autosal was thoroughly 
      cleaned and checked before station 200 deep salts were run, and the CTD 
      conductivity sensor was thoroughly cleaned both before and after station 
      202. No effect on conductivity values was noted after opening up CTD-1
      two separate times to repair the non-functioning multiplexer channel 
      (after stations 192 and 255).
      
      3.2.2.3.3. BOTTLE VS. CTD CONDUCTIVITY STATISTICAL SUMMARY
      
      The Hydros (SAVE/Year-2) calibrated bottle-minus-CTD conductivity 
      differences yield the following statistical results:

                               Mean conductivity
        Cruise  Pressure           difference       Standard   #values
        leg     range(dbars)  (bottle-CTD mmho/cm)  deviation  in mean
        ------  ------------- --------------------  ---------  -------
        SAVE-4  all pressures       -.00076          .00578     1944
                allp (4,2rej)       -.00039          .00227     1805
                press < 1500        -.00113          .00769      991
                press > 1500        -.00034          .00238      952
        SAVE-5  all pressures       -.00011          .00400     2311
                allp (4,2rej)       -.00012          .00137     2176
                press < 1500        -.00002          .00552     1174
                press > 1500        -.00021          .00104     1137
        --------------------------------------------------------------
               "4,2rei" means a 4,2 standard-deviation rejection 
                 filter was applied to the differences before 
                      generating the results.
      
      
      3.2.3. CTD DISSOLVED OXYGEN DATA
      3.2.3.1. CTD OXYGEN CORRECTIONS
      
      Dissolved oxygen data were acquired using a Sensormedics dissolved 
      oxygen sensor. During the three legs of the cruise, three oxygen sensors 
      were used. The original sensor on CTD #2 was used for stations 171 
      through 183, then failed during station 184. A replacement sensor did 
      not work on stations 185 and 210, then functioned normally on station 
      218 following various repairs. The CTD #1 oxygen sensor was used for all 
      other CTD casts except station 279, where a new sensor faded; the 
      original sensor was re-installed.
      
      CTD raw oxygen currents were extracted from the downcast pressure-series 
      data (upcast for station 202) at isopycnals corresponding to the upcast 
      check-samples. The differences between CTD and check-sample dissolved 
      oxygens were used to generate coefficients for the sensor model on a 
      station-by-station basis. Bottle oxygen values were weighted as needed 
      to optimize the fitting of CTD oxygen to discrete bottle samples.
      
      3.2.3.2. BOTTLE VS. CTD OXYGEN STATISTICAL SUMMARY
      
      After the CTD oxygen fitting was completed, the upcast bottle values 
      were compared to the corrected CTD oxygen values. The bottle-minus-CTD 
      oxygen differences resulted in the statistics below:

                                  Mean oxygen
        Cruise  Pressure           difference      Standard   #values
        leg     range(dbars)    (bottle-CTD ml/1)  deviation  in mean
        ------  -------------   -----------------  ---------  -------
        SAVE-4  all pressures       -.0009          .0813      1883
                allp (4,2rej)       +.0001          .0391      1740
                press < 1500        -.0044          .1095       963
                press > 1500        +.0027          .0312       920
        SAVE-5  all pressures       -.0032          .0780      2361
                allp (4,2rej)       +.0003          .0382      2193
                press < 1500        -.0071          .1036      1196
                press > 1500        +.0009          .0356      1165
        -------------------------------------------------------------
               * 4,2 standard deviation data rejection
      
      
      3.2.4. ADDITIONAL PROCESSING
      
      A software filter was used on a third of the casts to remove larger 
      conductivity or temperature spiking problems. Additionally, oxygen 
      spikes were filtered out of nearly half of the casts. Pressure did not 
      require filtering 0.35% of the time-series data were affected by the 
      filter. Two-thirds of the spiking problems were concentrated in the CTD-
      2/PRT-2 casts, where the distance between the secondary PRT and the 
      conductivity sensor resulted in poor signal match-up in high-gradient 
      areas, and station 202, with its fouled-sensor problem. After filtering, 
      the downcast (upcast for station 202) portion of each time-series was 
      pressure-sequenced into 2-decibar pressure intervals. A ship-roll. 
      filter was applied to each cast to disallow pressure reversals.
      
      The remaining density inversions in high-gradient regions cannot be 
      accounted for by a mis-match of pressure, temperature and conductivity 
      sensor response. Detailed examination of the raw data shows significant   
      mixing occurring in these areas because of ship roll. The ship-roll 
      filter resulted in a reduction in the amount and size of density 
      inversions.
      

      3.3. GENERAL COMMENTS/PROBLEMS
      
      There were 212 CTD rosette casts: three of these (station 178 casts 2 
      and 3, plus station 328 cast 1) were aborted because of various computer 
      problems, but another CTD cast was done immediately afterward at the 
      same locations. There is one pressure-sequenced CTD data set, to near 
      the ocean floor, for each of 209 stations. The data reported is all from 
      downcasts, excepting station 202, which is an upcast. The effect of the 
      initial sensor fouling on station 202's downcast was not possible to 
      filter out, while the upcast problems were mostly resolvable.
      
      The 0-decibar level of some casts was extrapolated using a quadratic fit 
      through the next three deeper levels. Recorded surface values were 
      rejected only when it appeared that the drift was caused by sensors 
      adjusting to the in-water transition; if there were any question that 
      the that the surface values might be real, the original data was 
      reported.
      
      Several shipboard time-series data sets had areas of missing or noisy 
      data. These casts were recovered by redigitizing the raw signal from 
      analog tape. A total of 9 data levels were interpolated in 8 casts: the 
      pressures for these interpolated data frames are listed in the CTD 
      Processing Notes as well as other shipboard or processing comments 
      regarding individual casts.
      
      During conductivity data calibrations it was noticed that there was an 
      apparent +.002 conductivity offset in the deep data for some stations. 
      This apparent offset appeared in both the downcasts and upcasts for the 
      affected stations. A similar phenomenon has been noticed before in this 
      and other CTDs where the raw conductivity value crosses from 32.768 to 
      32.767. On some stations, a -.002 shift back appears yet deeper, where 
      the raw conductivity value crosses back over to 32.767 from the other 
      direction. This is a problem specific to certain instruments, and 
      currently there is no correction. It is most noticeable in Atlantic 
      Ocean data because this particular conductivity crossover" value 
      typically occurs in deep water, where salinity is stable over many 
      hundreds of meters.
      
      The CTD oxygen sensor often requires several seconds in the water before 
      being wet enough to respond properly; this is manifested as low or high 
      CTD oxygen values at the start of some casts. Flow-dependence problems 
      occur when the lowering rate varies, or when the CTD is stopped, as at 
      the cast bottom or bottle trips, where depletion of oxygen at the sensor 
      causes lower oxygen readings. CTD downcast oxygen data are usually 
      smoother than upcast data because of the more constant lowering rate. 
      Station 202, the only upcast, demonstrates the typical oxygen depletion 
      effect at each bottle stop. Any delays or stops during the downcasts 
      that may have similarly affected the CTD oxygen data are documented in 
      the CTD Processing Notes.
      
      There were various winch, wire or rosette problems throughout the 
      cruise. These resulted in occasional stops, pauses or yoyos during 
      casts. Only those problems that may have affected the data continuity 
      have been noted. As mentioned above, these changes in the lowering rate 
      can affect oxygen in particular.


                         A16S (SAVE 5)  Smethie/McCartney  R/V Melville  1989
      __________________________________________________________________________
      __________________________________________________________________________


      4. DATA TABLES AND PLOTS
      4.1. STATION AND CAST DESCRIPTION
      
      Latitudes and longitudes were read from the ship's navigation system. 
      The time (GMT) is the beginning of the CTD up cast or the time the 
      messenger was sent for the Gerard casts. The bottom depth was read from 
      the PGR, and corrected according to Carter Tables (Carter, 1980). The 
      value (in meters) in the column "DAB" (Distance above bottom) was 
      obtained from the PGR, unless the "Comments" column reports altimeter, 
      as was the ocean depth. Note that the maximum sampling depth for the 
      Rosette casts is calculated from the corrected CTD data since the 
      deepest bottle may not have been closed at the deepest CTD sampling 
      point. If less than 36 bottles were sampled for the Rosette casts or 9 
      barrels for the Gerard casts, the number of samples taken are reported 
      in the comments. The complementary programs are reported in the 
      "Samples" column.
      

      4.2. TABULAR DATA, CTD, ROSETTE AND GERARD
      
      Station numbers are consecutive from the beginning to end of the cruise, 
      without interruption. Cast numbers are consecutive at each station, 
      including aborted casts. Meteorological data were collected by the 
      ship's officers and were copied from the Melville's Bridge Log. If more 
      than one CTD cast were done on a station, the deepest cast is reported.
      
      The headings in both the CTD data and ROSETTE and GERARD bottle data 
      have been abbreviated to PRESS, TEMP, and O2 for pressure (decibars), 
      temperature (degrees Celsius), and oxygen which is reported in both 
      (milliliters per liter) and (micromoles per kilogram). In the CTD data 
      listings, specific volume anomaly (centiliters/ton) was abbreviated SVA 
      and calculated according to Millero et al. (1980) and Fofonoff et al. 
      (1983), Sound Velocity (meters per second) to SVEL, (Chen and Millero, 
      1977), Dynamic Height (dynamic meters) to DYN HT, (Sverdrup et al., 
      1942), Vaisla Frequency (cycles per hour) to VAIS FREQ which uses a 
      subroutine by Bob Millard modified by Lynne Talley to incorporate 
      Gaussian weighting after the formulation of Breck Owens and N. P. 
      Fofonoff. In the bottle data listings, the headings have been 
      abbreviated to SAW NUM and SALT for Sample Number and Salinity 
      (Practical Salinity Units), AOU, PO4, NO3, SiO3, and NO2 for apparent 
      oxygen utilization, phosphate, nitrate, silicate, and nitrite 
      (micromoles/kilogram), respectively. Density anomalies in sigma-notation 
      follow the usual practice; e.g. sigma-theta (or sigma-0) is the 
      potential density in kg/m3 referenced to pressure=O, from which 1000 has 
      been subtracted. Potential temperature, 0, (degrees Celsius) has been 
      calculated according to Fofonoff (1977) and Bryden (1973) and depth 
      (meters) by Saunders (1981) and Mantyla (1982-1983).
      
      Throughout the bottle data report alphabetic characters may be found in 
      the tabular data. These characters have the following meaning:
      
      D  A salinity value, normally from a bottle sample, has been taken from 
         CTD records.
      G  Data value appears to be high or low as compared with the station 
         profile, however as compared with CTD trace the sample appears good.
      H  A pressure or temperature value, normally from CTD records, has been 
         taken from reversing thermometers.
      L  The sample bottle appears to have leaked. This usually refers to 
         Gerard barrels or the piggy-back Niskin and indicates that the samples 
         may be contaminated.
      P  The sampler either pre or post-tripped. This usually refers to Gerard 
         barrels and indicates that the samples may be contaminated.
      U  A data value is suspect, although no obvious reason has been found.
      
      Comments and investigation of these values are reported in the 
      appropriate leg's Bottle Data Processing Notes section. Surface samples 
      from the ship's underway pump line were assigned a separate cast number 
      and reported in the data table under the heading GERARD. This was not 
      the caw on Leg 4, these samples may have the rosette data cast number. 
      These surface samples are distinguished by an "H" footnote on the 
      pressure and reported in the GERARD section.
      

      4.3. STATION PLOTS
      
      The hydrographic station plots provide a visualization of the data that 
      is not possible from listings. The first few overlay plots represent the 
      entire leg. Then for each station, the upper plots on the even numbered 
      pages are CTD data, the lower two plots are bottle data. The odd 
      numbered pages are single station representation of potential 
      temperature vs. oxygen, phosphate, nitrate and silicate.
      


      5. ACKNOWLEDGEMENTS
      
      This data set was acquired under National Science Foundation Grant OCE 
      86-13330. The assistance provided by Dr. Neil Anderson is gratefully 
      acknowledged.
      
      

      5.  REFERENCES
      
      Armstrong, F. A. J., C. R. Steam, and J. D. H. Strickland, 1967. The 
         measurement of upwelling and subsequent biological processes by means of 
         the Technicon AutoAnalyzer and associated equipment, Deep-Sea Research 
         14,381-389.
      
      Atlas, E. L., S. W. Hager, L. 1. Gordon and P. K. Park, 1971. A 
         Practical Manual for Use of the Technicon AutoAnalyzer in Seawater 
         Nutrient Analyses; Revised. Technical Report 215, Reference 71-22. 
         Oregon State University, Department of Oceanography. 49 pp.
      
      Bernhardt, H. and A. Wilhelms, 1967. The continuous determination of low 
         level iron, soluble phosphate and total phosphate with the Auto-
         Analyzer, Technicon Symposia, Volume 1, 385-389.
         
      Brewer, P. G. and G. T. F. Wong, 1974. The determination and 
         distribution of iodate in South Atlantic waters. Journal of Marine 
         Research, 32,1:25-36.
         
      Bryden, H. L., 1973. New Polynomials for Thermal Expansion, Adiabatic 
         Temperature Gradient, Deep-Sea Research 20, 401-408.
      
      Carpenter, J. H., 1965. The Chesapeake Bay Institute technique for the 
         Winkler dissolved oxygen method, Limnology and Oceanography 10, 141-143.
      
      Carter, D. J. T., 1980 (Third Edition). Echo-Sounding Correction Tables, 
         Hydrographic Department, Ministry of Defense, Taunton Somerset.
      
      Chen, C.-T. and F. J. Millero, 1977. Speed of sound in seawater at high 
         pressures. Journal Acoustical Society of America, Volume 62, No. 5, 
         1129-1135.
         
      Fofonoff, N. P., 1977. Computation of Potential Temperature of Seawater 
         for an Arbitrary Reference Pressure. Deep-Sea Research 24, 489-49 1.
      
      Fofonoff, N. P. and R. C. Millard, 1983. Algorithms for Computation of 
         Fundamental Properties of Seawater. UNESCO Report No. 44,15-24.
      
      Hager, S. W., E. L. Atlas, L. D. Gordon, A. W. Mantyla, and P K. Park, 
         1972. A comparison at sea of manual and AutoAnalyzer analyses of 
         phosphate, nitrate, and silicate. Limnology and Oceanography 17 931-937.
         
      Lewis, E. L., 1980. The Practical Salinity Scale 1978 and Its 
         Antecedents. IEEE Journal of Oceanographic Engineering, OE-5,3-8.
      
      Mantyla, A. W., 1982-1983. Private correspondence.
      
      Millero, F. J., C.-T. Chen, A. Bradshaw and K. Schleicher, 1980. A New 
         High Pressure Equation of State for Seawater. Deep-Sea Research 27A, 
         255-264.
         
      Saunders, P. M., 198 1. Practical Conversion of Pressure to Depth. 
         Journal of Physical Oceanography 11, 573-574.
      
      STS/ODF, 1992. South Atlantic Ventilation Experiment (SAVE) Chemical, 
         Physical, and CTD Data Report, Legs 1, 2 and 3. SIO Reference #92-9.
      
      STS/ODF, 1992. HYDROS Chemical, Physical, and CTD Data Report, Leg 4. 
         SIO Reference #92-12.
      
      Sverdrup, H. U., M. W. Johnson, and R. H. Fleming, 1942. The Oceans, 
         Their Physics, Chemistry and General Biology, Prentice-Hall, Inc., 
         Englewood Cliff, NJ.
         UNESCO, 1981. Background papers and supporting data on the Practical 
         Salinity Scale, 1978. 
      
      UNESCO Technical Papers in Marine Science, No. 37, 144 p.


                         A16S (SAVE 5)  Smethie/McCartney  R/V Melville  1989
      __________________________________________________________________________
      __________________________________________________________________________


      CTD PROCESSING NOTES

      Stn  Cst  Remarks
      ---  ---  ----------------------------------------------------------------
      236  1  ODF-CTD #1 with TAMU transmissometer #100-D
      237  1  CTD #1
      238  1  CTD #1
      239  1  CTD #1
      240  1  CTD #1
      241  1  CTD #1
      242  1  CTD #1
      243  3  CTD #1;  -.002 psu salinity offset 3748-3980 dbars
      244  1  CTD #1
      245  1  CTD #1
      246  1  CTD #1
      247  1  CTD #1;  winch problem/stop at 4090 dbars down
      248  1  CTD #1;  only 11 oxygen samples: added bottles from stations 
                       247/249 for CTD oxygen fitting
      249  1  CTD #1
      250  1  CTD #1
      251  1  CTD #1;  7-minute delay in cast at 2945 dbars down
      252  2  CTD #1
      253  1  CTD #1;  7-minute delay in cast at 2750 dbars down
      254  1  CTD #1;  new end termination
      255  1  CTD #1;  transmissometer cleaned before cast; multiplexed channels 
                       (transmissometer altimeter, elapsed-time, trip-confirm) 
                       not working: replaced 3 chips in CTD after cast;  rosette 
                       hit bottom; found 2 kinks in wire
      256  1  CTD #1;  new end termination, pylon leads crossed: 12 bottles 
                       open, no bottle data 510-2500 dbars; CTD oxygen fitting 
                       used bottle data 
                       from this cast only
      257  1  CTD #1;  pylon leads switched back
      258  1  CTD #1
      259  2  CTD #1;  pylon problems, top 10 bottles not closed; CTD oxygen 
                       fitting used cast 3/Gerard bottle oxygens for top 500 
                       dbars
      260  1  CTD #1;  1370-dbar data level interpolated
      261  1  CTD #1
      262  1  CTD #1
      263  1  CTD #1;  new end termination
      264  1  CTD #1;  1202-dbar data level interpolated
      265  1  CTD #1
      266  1  CTD #1
      267  1  CTD #1
      268  1  CTD #1;  new end termination following CTD cable repair
      269  1  CTD #1;  yoyo 3655 dbars back to 3645 dbars on downcast
      270  1  CTD #1;  -.004 psu salinity dropout 3524-3556 dbars, then residual 
                       -.001 psu offset 3556-4906 dbars
      271  2  CTD #1;  8-minute delays in cast at 1180 + 1280 dbars, down
      272  1  CTD #1;  new end termination following CTD flag block replacement;
                       15-minute delay in cast at 11-15 dbars      
      273  1  CTD #1;  CTD wire rubbing on cheeks of flag block
      274  1  CTD #1
      275  1  CTD #1
      276  1  CTD #1
      277  1  CTD #1
      278  1  CTD #1
      279  1  CTD #1;  new CTD oxygen sensor installed/failed: no CTD oxygen 
                       data this  cast
      280  1  CTD #1;  original CTD oxygen sensor re-installed
      281  1  CTD #1
      282  1  CTD #1;  3-/7-minute delays in cast at 1785/1850 dbars, down
      283  1  CTD #1
      284  1  CTD #1
      285  1  CTD #1
      286  1  CTD #1
      287  1  CTD #1
      288  1  CTD #1
      289  1  CTD #1
      290  1  CTD #1
      291  2  CTD #1
      292  1  CTD #1
      293  1  CTD #1
      294  1  CTD #1
      295  1  CTD #1
      296  1  CTD #1;  yoyo 5125 dbars back to 5114 dbars on downcast; rinsed 
                       CTD connector cables after cast
      297  1  CTD #1
      298  2  CTD #1
      299  1  CTD #1
      300  1  CTD #1
      301  1  CTD #1
      302  2  CTD #1
      303  1  CTD #1
      304  1  CTD #1
      305  1  CTD #1
      306  1  CTD #1;  36-hour delay for engine repairs en route to station
      307  1  CTD #1
      308  1  CTD #1


                         A16S (SAVE 5)  Smethie/McCartney  R/V Melville  1989
      __________________________________________________________________________
      __________________________________________________________________________


      BOTTLE DATA PROCESSING NOTES
      
      Remarks for deleted or missing samples and footnoted data from SAVE Leg 
      5. Uncertainty of data (footnoted data) results in values that may not 
      fit the station profile, but are within the accuracy of the measurement. 
      Investigation of data may include comparison of bottle salinity and 
      oxygen with CTD data, comparison of Niskin/Gerard salinity, review of 
      data plots of station profile and adjoining stations, rereading of 
      charts (i.e., nutrients). CTD data is reported instead of bottle 
      salinity when comments refer to deleted salinity samples or missing for 
      various reasons. Oxygen and nutrient values are referred to in ml/l and 
      m/l, respectively. On Gerard casts, if there is a comment regarding the 
      Niskin bottle the corresponding Gerard barrel number follows the Niskin 
      number (i.e., 153/183 is Niskin 53 and Gerard 83).
      


      STATION  236
      104      Nutrients: NO2-"Bubbly" Junk in water. Analyst having 
               trouble with NO2, this sample @41db was affected.
      108      Nutrients: NO2-"Bubbly" Junk in water. NO2 missing-had no 
               readable peak @187db.
      133      delta-S .004 low at 4618db. Calc ok. CTD trace smooth. No 
               notes. Same value as sample 135. Probably bad draw or run. Delete 
               hydro salt (34.727).
               
      
      STATION  237
      1all     Salinity: general comment: Autosal drifting - Reruns 
               indicate drift not linear and rerun values too ragged to use. 
               Delete bottle salinities.
               
      
      STATION  240
      101      Sample Log: Missing salts and nuts. No salts or nutrients 
               drawn @1db.
      132      Hydro O2 @3401db .1 high compared to CTDO. Calc ok. No 
               notes. Delete bottle oxygen (5.66).
               
      
      STATION  241
      260/287  Sample Log: Bottom leaker. Bad spring. No other water 
               samples from Niskin#60. Niskin-Gerard S=.014 at 776db. Delete 
               bottle salinity (34.272).
               
      
      STATION  242
      124      delta-S .058 low at 2100db. Calc ok. Same value as 123 
               salt at 1900db. Apparent dupe draw or run. Delete bottle salinity 
               (34.757).
      126      delta-S .026 low at 2500db. Calc ok. Same value as 125 
               salt at 2300db. Apparent dupe draw or run. Delete bottle salinity 
               (34.847).
      127      delta-S .017 low at 2700db. Calc ok. Normal CTD gradient. 
               Apparent bad draw or run. Delete bottle salinity (34.869).
      134      Salinity: "Dirty bottle" delta-S .019 high at 3949db. 
               Calc ok. Same value as 133 at 3801db. Apparent dupe draw or run. 
               Delete bottle salinity (34.813).
               
      
      STATION  243
      192      Sample Log: Fork jumped wire, rest of cast did not trip. 
               Untripped barrels sent down again as cast 2.
      260      Sample Log: Bottom leaker. Niskin-Gerard S=.021 low at 
               2997db. Delete Niskin bottle salinity (34.865).
      309      Sample Log: Helium drawn between freon; vent leaks. 
               Oxygen:" stopper 797 switched with flask 798. Deleted discrete O2 
               until flask 798 recalibrated with stopper 797. Flasks 798 & 797 
               broken on station 248 when O2 box 9 fell apart, recalibration 
               could not be performed, Delete bottle oxygen (5.33) @300db.
      310      Delete O2 until flask 797 recalibrated with stopper 798. 
               Deleted discrete O2 until flask 797 recalibrated with stopper 
               798. Flasks 755 & 756 broken on station 248 when O2 box 9 fell 
               apart, recalibration could not be performed. Delete bottle oxygen 
               (5.47) @349db.
      451/481  Temperature: Thermometer Rack#5 did not flip. No 
               temperature @524db.
      454      Sample Log: Didn't close. No salinity @948db. Barium 
               drawn from Gerard.
               
      
      STATION  244
      121      Sample Log: O2 flask 756, lid 755. Oxygen: "stoppers 
               switched again" Deleted discrete O2 until flask 756 recalibrated 
               with stopper 755. Flasks 755 & 756 broken on station 248 when O2 
               box 9 fell apart, re calibration could not be performed. Delete 
               bottle oxygen (4.35) @1394db.
      122      Sample Log: O2 flask 755, lid 756. Deleted discrete O2 
               until flask 755 recalibrated with stopper 756. Flasks 755 & 756 
               broken on station 248 when O2 box 9 fell apart, recalibration 
               could not be performed. Delete bottle oxygen (4.20) @1498db.
               
      
      STATION  246
      120      PO4 missing @1298db. Original and rerun peaks both bad.
      132      Sample Log: Missing drain. No water samples @3400db.
               
               
      STATION  248
      101      Sample Log: Drain fell apart on opening. Assume means 
               disk came off spigot. Oxygen flasks broken, no oxygen samples 
               @2db.
      102      Oxygen flasks broken, no oxygen samples @25db.
      103      Oxygen flasks broken, no oxygen samples @54db.
      104      Sample Log: Spigot opened while bringing aboard. No gases 
               sampled @77db. Oxygen flasks broken, no oxygen samples @77db.
      105      Oxygen flasks broken, no oxygen samples @98db.
      106      Oxygen flasks broken, no oxygen samples @152db.
      112      Sample Log: Retake helium. Oxygen flasks broken, no 
               oxygen samples @499db.
      114      Sample Log: Bottom leaker. delta-S .000 at 697db. Oxygen 
               flasks broken, no oxygen samples.
      116      Oxygen flasks broken, no oxygen samples @894db.
      118      Oxygen flasks broken, no oxygen samples @1096db.
      120      Oxygen flasks broken, no oxygen samples @1293db.
      121      Oxygen flasks broken, no oxygen samples @1293db.
      122      Oxygen flasks broken, no oxygen samples @1496db.
      123      Oxygen flasks broken, no oxygen samples @1596db.
      125      Oxygen flasks broken, no oxygen samples @1897db.
      126      Oxygen flasks broken, no oxygen samples @2099db.
      127      Oxygen flasks broken, no oxygen samples @2300db.
      128      Oxygen flasks broken, no oxygen samples @2498db.
      129      Oxygen flasks broken, no oxygen samples @270ldb.
      131      Oxygen flasks broken, no oxygen samples @3099db.
      132      Oxygen flasks broken, no oxygen samples @3299db.
      133      Oxygen flasks broken, no oxygen samples @3498db.
      134      Oxygen flasks broken, no oxygen samples @3702db.
      135      Oxygen flasks broken, no oxygen samples @3899db.
      136      Sample Log: Retake helium. Oxygen flasks broken, no 
               oxygen samples @3989db.
               
 
      STATION  249
      101-136  Delete all bottle salinities; problem with 
               temperature in salinity lab.
               
      
      STATION  250
      104      Sample Log: Drain broken, probably broken on pinger. No 
               water samples @100db.
               
      
      STATION  251
      111      delta-S .183 high at 378db. Calc ok. Normal gradient. No 
               notes. Salt value .007 lower than 110 salt value which could 
               indicate possible dupe draw. Other water samples ok. Delete 
               bottle salinity (34.973).
      171      Sample Log: Bottom endcap open. No water samples 49db.
               
      
      STATION  252
      160      Sample Log: Empty. No salt sample for Gerard 89 check 
               @4352db. Gerard 89 salt agrees with rosette salts and rest of 
               Cast 1 salts.
      222      delta-S .051 at 1651db. Calc ok. Normal gradient, no 
               notes. No apparent reason for large difference here. Other water 
               samples ok (02 min). Delete bottle salinity (34.538).
      3all     Niskin salinities were not drawn. No explanation given, 
               must just have been sampling oversight.
               
      
      STATION  253
      116      Nutrients high @897db, same values as 117, assume dupe 
               draw. Delete nutrients (PO4=2.08, NO2=0.00, NO3=31.4, S103=32.1).
      130      Discrete O2 appears .1 low at 3196db. Agrees with CTDO, 
               conductivity and temperature feature this level. Footnote "G" 
               indicating sample appears low, but verifies with CTD trace.
      136      delta-S .162 low at 4322db. Calc ok. Salt bottle #PP47 on 
               Sample Log & #4277 on Salinity Data Sheet. Assume mixup with 
               sample bottles. Delete bottle salinity (34.843).
      256      Sample Log: Hung up, no sample. Gerard 86 salt @802db 
               agrees with other salts this level so Gerard ok.
      260      Niskin-Gerard S=.023 at 826db. Calc ok. Gerard 89 salt 
               agrees with other salts this level so assume Niskin leaked and 
               Gerard sample ok. No other samples from Niskin 60. Delete Niskin 
               bottle salinity (34.247).
               
      
      STATION  254
      101      Nutrients: Evidently too much junk in water to resolve 
               peaks on NO2. No NO2 @6db.
      136      Discrete O2 about .1 high at 4368db. CTDO increasing at 
               bottom but not this much. Only 2 other stations have unexplained 
               high O2 for Niskin #36. Possibly drawer forgot to flush pickling 
               syringes. Delete bottle oxygen (5.16).
               
      
      STATION  256
      108      delta-S .012 low at 3897db. Calc ok. Normal gradient. 
               Same value as sample 109. Assume dupe draw. Delete bottle 
               salinity  (34.681).
      124      No O2 drawn @10db, Keeling CO2 sample.
               
      
      STATION  259
      181/152  Sample Log: Too shallow. Pre-tripped at 1631db vs. 
               3800db intended depth. Niskin-Gerard S=.008 due poor flush Cast 
               not repeated due bad weather. Samples drawn & analyzed. Suggested 
               footnote: "Pretrip, depth uncertain by +/- 50 meters." "P"
      182/153  Sample Log: Too shallow, leaking but vent is tight. 
               Pretripped at 2127db vs. 4200db intended depth. Niskin-Gerard 
               S=.024 due poor flush and probable Gerard leak. Unable to open 
               Gerard 82 lid after this cast. Cast not repeated due bad weather. 
               Samples drawn & analyzed. Suggested footnote: "Pretrip, depth 
               uncertain by +/- 100 meters." "P"
      183/154  Sample Log: Too shallow. Pretripped at 2489db vs. 
               intended depth of 4440db. Niskin-Gerard S=.009 due poor flush. 
               Cast not repeated due bad weather. Samples drawn & analyzed 
               except no Argon this station. Suggested footnote: "Pretrip, depth 
               uncertain by +/- 50 meters." "P"
      185      Sample Log: Did not trip and no messenger on top. It did 
               drop its messenger. No water samples. Cast not repeated due bad 
               weather.
      186      Sample Log: Tripped at the surface. No water samples 
               drawn. Cast not repeated due bad weather.
      187      Tripped at the surface per DSRTs. No water samples 
               drawn. Cast not repeated due bad weather.
      188      Tripped at the surface per DSRTs. No water samples 
               drawn. Cast not repeated due bad weather.
      189      Tripped at the surface per DSRTs. No water samples 
               drawn. Cast not repeated due bad weather.
      151      Delete low PO4 (2.09 kg, 2.14 1) @3371db.
      201      Sample Log: Did not trip. Bad Pylon
      202      Sample Log: Did not trip. Bad Pylon
      203      Sample Log: Did not trip. Bad Pylon
      204      Sample Log: Did not trip. Bad Pylon
      205      Sample Log: Did not trip. Bad Pylon
      206      Sample Log: Did not trip. Bad Pylon. No water samples 
               @178db.
      207      Sample Log: Did not trip. Bad Pylon. No water samples 
               @248db.
      208      Sample Log: Did not trip. Bad Pylon. No water samples 
               @299db.
      209      Sample Log: Did not trip. Bad Pylon. No water samples 
               @371db.
      210      Sample Log: Did not trip. Bad Pylon. No water samples 
               @427db.
      211      No salt drawn @522db per sample log. Other water samples 
               ok. No notes. Forgotten? All three (silicate, phosphate and 
               nitrate) do not fit at all with the vertical section and are 
               pretty clearly erroneous. - L. Talley 920409 Bottle appears to 
               have tripped at ~300db, Delete all water samples (O2=5.91, 
               PO4=1.77, NO2=0.01, NO3=25.9, SiO3=13.3).
      212      No salt drawn @623db per sample log. Other water samples 
               ok. No notes. Forgotten?
      215      delta-S .075 low @988db. Calc ok. Same value as 214. 
               Assume dupe draw. Delete bottle salinity (34.266).
      216      delta-S .016 high at 1096db. All water samples appear to 
               be from about 100db. No notes. Assume bad trip or bad leak. 
               Delete all water samples (S=34.441, O2=5.16, PO4=1.00, NO2=0.08, 
               NO3=12.3, SiO3=12.8).
      222      L. Talley indicated PO4 high. Investigation of the data 
               shows good comparison with CTDO2 even though bottle oxygen 
               appears low. Silicate appears high, but only fits lower in the 
               water column. NO3 appears high, also fits lower in the water 
               column. Salinity agrees with CTD .003 so both salinity and oxygen 
               show that something is different here, and appears to be real. 
               ODF has suggested that the samples be footnoted either "U" for 
               uncertain or "G" for good and verified by other data parameters. 
               Foot note PO4 "U" for uncertain.
      228      Salinity: "loose top" delta-S .004 high at 3112db. Delete 
               bottle salinity (34.741).
      234      Sample Log: Lanyard bung up. No water samples @4298db.
      356      Niskin-Gerard S=.312 at 421db. Calc ok. No notes. 356 
               water samples appear to be surface water. Gerard 86 salt agrees 
               with CTD salt this level so Gerard sample good. Delete all Niskin 
               water samples (S=34.526, O2=5.91, PO4=0.78, NO2=0.09, NO3=9.0, 
               SiO3=2.9).
      360      Sample Log: Leaked. Details not noted. Salinity: "jumpy" 
               Niskin-Gerard S=-.007 at 1325db. Calc ok. Normal gradient small 
               leak in Niskin 60 likely and Gerard 89 looks ok. Freon & barium. 
               also drawn from Niskin. Suggested footnote: "Sample Log note and 
               .007 difference between Niskin and Gerard salts indicate slight 
               leak in Niskin sample 360." "L"
               
      
      STATION  260
      102      No discrete O2 @7db, Keeling CO2 samples.
      171      Sample Log: Did not fire. No further explanation. No 
               notes Conops or Deck Log. No water samples @79db.
      116      Sample Log: Lanyard hung on frame during recovery, 
               lifted top stopper. Discrete O2 @1059db about .12 high compared 
               to CTDO. No freon or helium. drawn this sample. Salt & nutrients 
               ok. Delete bottle oxygen (4.62).
      128      PO4 @3200db low. Footnote PO4 "U" uncertain.
      129      PO4 @3402db low. Footnote PO4 "U" uncertain.
      130      PO4 .05 low at 3599db. Calc ok, peaks fair. Air in PO4 
               line before 130 and after 136. Footnote PO4 "U" uncertain.
      131      PO4 .04 low at 3799db. Calc ok, peaks fair. Air in PO4 
               fine before 130 and after 136. Footnote PO4 "U" uncertain.
      132      PO4 .04 low at 3999db. Calc ok, peaks fair. Air in PO4 
               line before 130 and after 136. Footnote PO4 "U" uncertain.
      133      PO4 .03 low at 4198db. Calc ok, peaks fair. Air in PO4 
               line before 130 and after 136. Footnote PO4 "U" uncertain.
      134      PO4 .03 low at 4349db. Calc ok, peaks fair. Air in PO4 
               line before 130 and after 136. Footnote PO4 "U" uncertain.
      135      PO4 .O2 low at 4499db. Calc ok, peaks fair. Air in PO4 
               line before 130 and after 136. Footnote PO4 "U" uncertain.
      136      PO4 .04 low at 4550db. Calc ok, peaks fair. Air in PO4 
               line before 130 and after 136. Footnote PO4 "U" uncertain.
               
      
      STATION  263
      106      Salinity: "Lost" No reason given. No hydro salt 249db.
               
      
      STATION  265
      131      delta-S .006 high at 4402db. Calc ok. Smooth CTD 
               gradient. Probable bad draw or run. Delete bottle salinity 
               (34.680).
               
      
      STATION  266
      111      Salinity: "may leak a little" delta-S .004 high at 601db. 
               Same salt bottle used subsequent station with no problem. Delete 
               bottle salinity (34.224).
      171      Sample Log: Lanyard hung, no sample. No water samples 
               @98db.
               
      
      STATION  267
      101      Oxygen: "broken flask, no sample" No oxygen sample @4db.
      125      O2 .04 high at 3199db compared to CTDO. Calc ok. Possibly 
               drawn from Niskin 26?. Delete bottle oxygen (4.84).
      127      Sample Log: Vent leaks. delta-S .001 low at 3600db. Other 
               water samples also ok. NO3 @3600db 1.0 higher than adjacent 
               stations. Rerun (between 130 & 131) was used which was definitely 
               higher than original, poorer, peak. All subsequent NO3 values 
               also higher than adjacent stations. Footnote high NO3 as 
               uncertain "U".
      128      NO3 @3802db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      129      NO3 @4004db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      130      NO3 @4200db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      131      NO3 @4399db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      132      NO3 @4596db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      133      NO3 @4802db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      134      NO3 @5000db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      135      NO3 @5198db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
      136      NO3 @5253db about 1.0 higher than adjacent stations. Peak 
               not perfect but definitely high. Footnote high NO3 as uncertain 
               "U".
               
      
      STATION  268
      117      Sample Log: Valve pushed in. delta-S .071 low at 1498db. 
               Calc ok. Other water samples also indicate leak. Delete all water 
               samples (S=34.684, O2=4.31, PO4=2.22, NO2=0.00, NO3=32.8, 
               SiO3=81.1).
      127      NO3 high @3401 db, footnote "U".
      128      NO3 high @3608db, footnote "U".
      129      NO3 high @3802db, footnote "U".
      130      NO3 high @4001db, footnote "U".
      136      Oxygen: "Forgot to write down value, lost" No oxygen data 
               @5146db.
               
      
      STATION  270
      136      Sample Log: Tritium drawn after nuts. O2 .4 high at 
               5638db compared to CTDO and adjacent stations. Calc ok. Assume 
               draw or titration. Delete bottle oxygen (6.01).
               
      
      STATION  271
      1all     No temperatures, forgot to read DSRTs before next Gerard 
               cast. Calculating barrel depths based on corrected wire length, 
               pinger distance from bottom, and corrected bottom depth gives 
               good agreement between Gerard salts and rosette salts.
      211      No nutrients @605db per nutrient data sheet. Ok per 
               sample log. Assume not drawn.
      217      O2 .4 high compared to CTDO at 1658db. Calc ok. Delete 
               bottle oxygen (4.83).
      223      O2 .04 high compared to CTDO at 2796db. Calc ok. Delete 
               bottle oxygen (4.88).
      228      delta-S .005 high at 3799db. Calc ok. Smooth CTD 
               gradient. Note on salt data sheet indicates possible salt crystal 
               contamination. Delete bottle salinity (34.677).
      3all     Sample Log: Cast aborted, double pinging after two 
               barrels. No samples.
               451/487  DSRTs indicate posttrip; TP 1505db vs. intended depth of 
               2900m. Delete Niskin and Gerard level. Post trip. See 451.
      452/488  Sample Log: Rigged wrong, didn't close. No Niskin salts 
               or temp. DSRTs on barrels above & below indicate posttrip. Delete 
               Niskin and Gerard level. Posttrip. See 452.
      453/489  DSRTs indicate posttrip; TP 1746db vs. intended depth of 
               3800m. Delete Niskin and Gerard level. Post trip. See 453.
      456      Sample Log: Rigged wrong, didn't close. No Salt for 
               Gerard check @2366db. See 486. Gerard 86 salt agrees with rosette 
               salt this level. Gerard sample ok.
      459/485  Sample Log: Rigged wrong, did not close. No salt for 
               Gerard check @2O27db. See 485. Gerard 85 salt is .005 higher than 
               rosette salt this level. Gerard sample probably ok.
      553/589  DSRTs indicate pre or posttrip; TP 1337db vs. 3600m 
               intended depth. Niskin-Gerard S=.014 indicating poor flush. 
               Delete Niskin and Gerard level. Post?-trip. See 553.
               
      
      STATION  272
      113      Salinity: "top loose, leaks" delta-S .005 high at 801db. 
               Normal CTD gradient. Delete bottle salinity (34.663).
      134      delta-S .005 high at 4753db. Calc ok. Same value as 132. 
               Possible dupe draw. Delete bottle salinity (34.659).
      171      Sample Log: Smashed drain. No water samples @148db.
               
      
      STATION  273
      113      Sample Log: No sample, end caps lost. No water samples 
               @801db.
      131      Sample Log: 6 pCO2 samples, nothing else. No water 
               samples @4000db.
               
      
      STATION  274
      132      NO3 1.5 high @4200db. Poor peak but high. Rerun after 
               standards had worse peak. Delete nitrate (36.2).
               
      
      STATION  275
      122      Sample Log: Bottom end cap hung up. No sample @1803db.
      135      O2 .12 high @3938db. Calc ok. CTDO shows smooth gradient. 
               Delete bottle oxygen (5.40).
               
      
      STATION  279
      120      Keeling & LDGO CO2 only. No hydro S, O2 or nutrients 
               @4db.
               
      
      STATION  280
      125      PCO2 only. No other water samples @903db.
               
      
      STATION  281
      101      No Salt, O2 or nutrients @4db, Keeling CO2.
      106      No Salt, O2 or nutrients @200db, Keeling CO2.
      108      No Salt, O2 or nutrients @247db, Keeling CO2.
      111      No Salt, O2 or nutrients @347db, Keeling CO2.
      114      No Salt, O2 or nutrients @499db, Keeling CO2.
      116      No Salt, O2 or nutrients @597db, Keeling CO2.
      118      No Salt, O2 or nutrients @748db, Keeling CO2.
      120      No Salt, O2 or nutrients @998db, Keeling CO2.
      123      No Salt, O2 or nutrients @1497db, Keeling CO2.
      126      No Salt, O2 or nutrients @1999db, Keeling CO2.
      129      No Salt, O2 or nutrients @2484db, Keeling CO2.
      132      No Salt, O2 or nutrients @3010db, Keeling CO2.
      135      No Salt, O2 or nutrients @3628db, Keeling CO2.
               
      
      STATION  281 (continued)
      136      S103 6. too high. Delete S103 (140.6). NO2.03 high, not 
               sure what caused this. Footnote NO2 "U" for uncertain.
      171      No Salt, O2 or nutrients @126db, Keeling CO2.
               
      
      STATION  282
      115      All water samples appear to be from about 2000db vs. 5 db 
               when tripped. Top lanyard found broken on recovery per Deck Log. 
               Delete all water samples (S=34.709, O2=4.67, PO4=2.18, NO2=0.00, 
               NO3=33.9, SiO3=119.1).
      129      delta-S .004 high at 14OOdb. Calc ok. CTD trace smooth 
               and indicates sal max closer to 1500db. No notes. No apparent 
               problems with other water samples. Delete bottle salinity 
               (34.720).
               
      
      STATION  283
      135      Sample Log: Lid not closed. 5m above 136. Suspended 
               particles checked on sample log. Deck Log note: "top of Niskin 35 
               did not close completely slightly askew." No other samples drawn 
               @1714db so sample integrity unknown.
               
      
      STATION  284
      131      Discrete O2 .2 high at 1297db. Calc ok. CTDO down & up 
               traces show min not max this level. O2 values similar to 132 
               value so possibly drawn from Niskin32 in error. Delete bottle 
               oxygen 
               (4.39).
      287      Sample Log: Went down without washer on valve arm. Assume 
               means no o-ring on valve cap. Niskin Gerard S=.003 at 889db. 
               Probable slight leak. Suggested footnote: "No o-ring on valve 
               cap. Probable slight leak." "L"
               
      
      STATION  286
      110      Sample Log: Air leak. delta-S .000 at 551db. Other water 
               samples also ok.
      122      Discrete O2 .1 high. Calc ok. No notes. CTDO shows 
               feature this level both down & up but only about 1/2 as high. 
               Nutrients & salt also have feature but salt is proportional to 
               CTD down & up traces. Suggest: FOOTNOTE "U"
               
      
      STATION  287
      112      Sample Log: Air leak, sample leaked out on deck. No water 
               samples drawn @801db.
      113      delta-S .014 high at 948db. Calc ok. High gradient. 
               Nutrients ok (NO3 & PO4 max). O2 problem apparently unrelated is 
               described below. O2 value appears about .07 high at 948db 
               compared to CTDO down & up traces. Oxygen analyst indicated 
               sample was over-titrated, but sample does not give good results. 
               Delete bottle oxygen (4.00).
      259      Sample Log: No salts drawn. Sampling error @5203db, they 
               should have been. Freon & barium were drawn. Gerard (#289) salt 
               agrees well with CTD salt trace.
      260      Sample Log: No salts drawn. Sampling error @5380db, they 
               should have been. Freon & barium were drawn. Gerard (290) salt 
               agrees well with CTD salt trace.
      353      Salinity: "top loose" Niskin-Gerard S=.009 at 208db. 
               Gerard salt looks ok. Delete Niskin salinity (34.147).
               
      
      STATION  291
      160      Niskin-Gerard S=.005 at 5449db. Calc ok. No notes. Gerard 
               (190) salt agrees with CTD and other Argon cast salts this level. 
               No other samples taken Niskin 160. Delete Niskin salinity 
               (34.671).
               
      
      STATION  292
      130      SIL 1.6 higher than 131 SIL tripped at same level 
               (4198db). 131 value in better agreement with adjacent values and 
               130 has poor peak. Delete silicate value (129.3).
               
               
      STATION  293
      116      Sample Log: Hung up. No water samples @1502db.
               
      
      STATION  294
      121      delta-S .018 low at 2198db. Calc ok. Same value as 120 
               salt so possible dupe draw. CTDs noisy but not this much. O2 & 
               PO4 look ok. NO3 1.0 high and SIL 2.0 high. NO3 peak poor, SIL 
               peak ok. Calc ok. Delete bottle salinity (34.773).
      136      Discrete O2 @5242db .33 ml/L high compared to adjacent 
               samples and CTDO traces. Calc ok. Assume bad draw or titration. 
               Deleted bottle oxygen (5.51).
      257/288  Thermometer: Lanyard hang-up, therms did not reverse. No 
               temperature @4716db. Sample Log: Lid not completely closed. 
               Niskin-Gerard S=-.001 at 4699db. Gerard sample ok.
      259/289  Sample Log: Air leak. Salinity: "Perhaps drawn quite 
               late" Niskin-Gerard S=-.002 but both DSRTs and salinities 
               indicate Niskin and Gerard tripped at about 2550db instead of 
               5080db as intended. Probably post-tripped. See 290. Suggested 
               footnote: "Post-trip, poor flush.".
      260/290  Sample Log: Air leak. Salinity: "Perhaps drawn quite 
               late" Niskin-Gerard S=.008 at 5241db. Gerard salt agrees with 
               rosette & CTD salts. Assume Niskin leaked. Freon & barium also 
               drawn from Niskin. Delete Niskin salinity (34.673). Gerard 
               samples looks good.
      360/392  Niskin salt low at 1476db indicating leak. No notes but 
               same Niskin leaked last cast. Barium also drawn from Niskin #60. 
               Delete bottle salinity (34.596). Sample Log: Air leak. Niskin-
               Gerard S=-.013 at 1476db. Gerard salt agrees with rosette & CTD 
               salts. Assume Gerard ok.
               
      
      STATION  295
      112      Sample Log: Hung up/no sample. No water samples @849db.
               
               
      STATION  296
      133      delta-S .004 low at 4797db. Calc ok. Normal CTD gradient. 
               Same value as 134, possible dupe draw. Delete bottle salinity 
               (34.667).
               
      
      STATION  297
      130      delta-S .006 high at 3898db. Calc ok. Normal CTD 
               gradient. Possible salt crystal from cap got into sample. 
               Nutrients ok. Delete bottle salinity (34.708).
               
      
      STATION  298
      154/185  Sample Log: Didn't trip. No water @3022db. Gerard (185) 
               salt agrees with CTD salt.
      157/188  Sample Log: Didn't trip. No water @4515db. Gerard (188) 
               salt agrees with CTD salt.
               
      
      STATION  300
      131      delta-S .004 high at 3899db. Calc ok. Normal gradient. No 
               notes. Other water samples ok. Deleted bottle salinity (34.700).
               
      
      STATION  302
      210      delta-S .051 high at 473db. Calc ok. Normal gradient. No 
               notes or explanation Other water samples ok (02 min). Delete 
               bottle salinity (34.880).
      235      PO4.42 high at 4550db. Calc & peak ok. Assume 
               contamination problem. Delete phosphate (2.78).
      236      delta-S .002 to .003 high at 4643db. Steady increase in 
               each Autosal run indicating possible salt crystal contamination 
               from bottle cap. Delete bottle salinity (34.671).
               

      STATION  303
      113      Sample Log: Drained for salts. No salinity sample @651db.
      115      Sample Log: Empty for salts. No hydro S @803db.
      117      Sample Log: Low for salts. delta-S .002 high at 1002db. 
               Hydro O2 low at 1003db per CTDO calibration. Calc ok, no notes. 
               This is Keeling CO2 bottle so bottle half empty when O2 drawn. O2 
               .22 lower than Niskin 16 tripped at same level. Delete bottle 
               oxygen (5.19).
      124      Sample Log: Empty for salts, barely sampled nuts. No 
               bottle salinity @2110db.
      131      Sample Log: Freon drawn after TCO2. Does not effect 
               samples @355ldb. delta-S .008 high at 3550db. Calc ok. Small 
               spike in raw CTD S trace this level but block averaged data has 
               smooth normal gradient. No notes. Delete bottle salinity 
               (34.785).
               
      
      STATION  304
      134      delta-S .080 high at 3696db. Calc ok. All water samples 
               appear to be from about 3475db. Delete all water samples 
               (S=34.779, O2=5.19, PO4=2.00, NO2=0.00, NO3=28.8, SiO3=86.1)
               
      
      STATION  305
      113      Oxygen @10OOdb is low. Appears to have drawn from bottle 
               14. Delete oxygen (5.33).
      171      Sample Log: Sample cock sheared off during recovery, 
               sample lost. No water samples @129db.
               
      
      STATION  306
      119      Oxygen data sheet "bubble - large variety" O2 .2 high 
               @1954db. Same value as 120. Smooth CTDO trace. Delete bottle 
               oxygen (4.75).
      453      Salinity data sheet: "Junk in water" Niskin-Gerard S=.006 
               at 5049db. Calc ok. Niskin is high and Gerard (88) agrees with 
               CTD, rosette and other samples this Argon cast. No other sample 
               drawn this Niskin. Delete Niskin salinity (34.676).
      457      Niskin-Gerard S=.011 at 4862db. Calc ok. Niskin is high 
               and Gerard (83) agrees with CTD, rosette and other samples this 
               cast. Freon and Barium also drawn this Niskin. Niskin salt is 
               similar to 454 salt which was the adjacent bottle in the rack. 
               Possibly 457 was misdrawn and the other samples are ok. No notes. 
               Delete Niskin salinity (34.681).
      459      Sample Log: Empty - didn't trip. No Niskin salt or hydro 
               T & P at 5025db. Gerard salt (485) agrees with CTD, rosette and 
               other samples this Argon cast.
               
      
      STATION  307
      128      Sample Log: Thermometer lanyard caught in bottle top. 
               Sample discarded. Nutrients & salinity run; both indicate severe 
               leak@3301db. Delete all water samples (S=34.893, O2=1.35, 
               PO4=1.35, NO2=0.01, NO3=19.3, SiO3=37.4).
      186      Sample Log: Not latched, water squirting out of lid on 
               recovery. Niskin-Gerard S=-.007. Niskin sample (56) agrees with 
               other samples this level and Gerard salt is high. After cast 
               found wrong size air vent plug had been used. (New {WHOI} barrels 
               have slightly different diameter hole in lid for air vent plug 
               than the old (yellow- hooded) barrels.) Sample Log indicates 
               Argon and radium 228 may have been taken from Gerard. Leave bad 
               Gerard salt in report to indicate problem, footnote "U".
               
      
      STATION  308
      106      delta-S .258 low at 199db. Calc ok. Same value at 107 
               salt. Other water samples ok. Assume 106 salt drawn from Niskin 
               7. Delete bottle salinity (34.626).
      


                              A16S (SAVE 5)  Radiocarbon  stlund/Grall  1989
      __________________________________________________________________________
      __________________________________________________________________________



                                UNIVERSITY OF MIAMI
                ROSENSTIEL SCHOOL OF MARINE AND ATMOSPHERIC SCIENCE
                                  MIAMI, FL 33149
     
                               S.A.V.E. RADIOCARBON
                      SOUTH ATLANTIC VENTILATION EXPERIMENT
                                    1987-1989
     
                                TRITIUM LABORATORY
                                 DATA REPORT # 18
                                        by
                        H. Gte stlund and Charlene Grall
     
     
     This report constitutes the Final Report for the following grant:
     
     NSF OCE-86-13329                                          September 1992
     
     
     TRITIUM LABORATORY DATA REPORTS
     
     #1   TRITIUM IN THE TROPOSPHERE AND SURFACE WATER OF NORTH ATLANTIC OCEAN 
          1964-70, H.G. stlund, R.D. Stearns, and R. Brescher. July 1971.
     
     #11  ANTARCTIC TRITIUM 1977-1979, A.S. Mason and H.G. stlund. November 
          1981.
     
     #12  GEOSECS TRITIUM, Atlantic Ocean 1972-73, Pacific Ocean 1973-74, 
          Indian Ocean 1977-78, Station 347 Revisits, H.G. stlund and R. 
          Brescher.  December 1982.
     
     #13  NAGS TRITIUM, North Atlantic Gyre Studies and Associated Projects, 
          H.G. stlund. June 1984.
     
     #14  ATMOSPHERIC TRITIUM 1968-1984, H.G. stlund and A.S. Mason. April 
          1985.
     
     #15  EQUATORIAL PACIFIC TRITIUM, H.G. stlund, C. Grall, and R.E. 
          Brescher. April 1986.
     
     #16  TTO NORTH AND TROPICAL ATLANTIC TRITIUM AND RADIOCARBON, H.G. 
          stlund and C. Grall. February 1987.
     
     #17  INDIGO 1985-1987, INDIAN OCEAN RADIOCARBON. H.G. stlund and C. 
          Grall. April 1988.
     
     #18  S.A.V.E. RADIOCARBON, South Atlantic Ventilation Experiment, 1987-
          1989.  H.G. stlund and C. Grall. November 1992. THIS REPORT.
     
     NOTE:  Data Report #s 2,3,4,5,6,7,8,9,10 have been superseded by #s 
            12,13 and 14. The measurement results of #12 are also available in 
            Vol. 7 of the GEOSECS ATLAS.
     
     
     PREFACE
     
     This report presents all the radiocarbon measurements produced from the 
     six S.A.V.E Cruises 1987-1989. The following informal Data Releases 
     include all measurement results previously reported. Additional quality 
     control has slightly changed some earlier data which are hereby 
     superseded.
     
       #89-05 S.A.V.E. Radiocarbon Results, Legs 1 and 2. 
       #89-38 S.A.V.E. Radiocarbon Results, Legs 2 and 3. 
       #90-32 S.A.V.E. Radiocarbon Results, Legs 4,5 and HYDROS Leg 4. 
       #91-56 S.A.V.E. Radiocarbon Results, Legs 3,4,5 and HYDROS Leg 4.
     
     The data in this report are hereby in the public domain to, be used by 
     anyone. Conventional reference is appreciated.
     
     Copies of this Data Report, or any other Tritium Laboratory Data Report, 
     may be obtained by addressing the Tritium Laboratory, RSMAS, University 
     of Miami, 4600 Rickenbacker Causeway, Miami, Florida 33149, U.S.A.
     
     A 5-1/4" floppy disk, containing all radiocarbon data in this report in 
     addition to some hydrographic data, in ASCII format, is available upon 
     request. We hope that this data set will be used extensively in many 
     modeling studies in the years to come.
     
     
     ACKNOWLEDGMENTS
     
     The measurement of all the radiocarbon samples and the production of 
     this report were carried out under National Science Foundation Grant 
     NSF-OCE-86-13329. We are very grateful for their long term support. We 
     also thank the technical staff of the Ocean Data Facility at Scripps 
     Institution of Oceanography for the radiocarbon sample collection and 
     shipboard extraction. We sincerely appreciate the efforts of the chief 
     scientist to include as many sample collections as they did especially 
     after the untimely loss of the Gerard barrels on the first cruise of 
     this project. M. Stuiver and T. Saling at Quaternary Research Office, 
     University of Washington, made the numerous and excellent 13C 
     measurements which is hereby gratefully acknowledged.
     
     
     TABLE OF CONTENTS
     
       TRITIUM LABORATORY DATA REPORTS 
       PREFACE 
       ACKNOWLEDGEMENTS 
       (S.A.V.E.) RADIOCARBON SOUTH ATLANTIC VENTILATION EXPERIMENT, 1987-1989.

               I  INTRODUCTION 
              II  CRUISE DESCRIPTIONS  
             III  TECHNICAL PROCEDURES 
              IV  NOTES ON SCALES  
               V  ACCURACY AND ERRORS 
              VI  HYDROGRAPHIC DATA . . 
             VII  COMMENTS TO FIGURES AND TABLES 
            VIII  REFERENCES 

       APPENDIX 
       SECTIONS (SAVE 5 - A16S only)

       
       
       
     S.A.V.E. RADIOCARBON SOUTH ATLANTIC VENTILATION EXPERIMENT, 1987-1989
     
     
     I.  INTRODUCTION
     
     The project called Transient Tracers in the Ocean, TTO was initiated it 
     1980 with the intent to study the Atlantic Ocean. The North Atlantic 
     Study (NAS) and Tropical Atlantic Study (TAS) scientific cruises 
     continued only as far south as 10S. The South Atlantic Ventilation 
     Experiment (SAVE) expeditions traversed as far south as 53S and east to 
     Africa. Through the use of various tracers, the program investigated 
     circulation, mixing and ventilation of the South Atlantic Ocean. 
     Radiocarbon (14C) is considered an important tracer to study because it 
     helps provide information on rates of internal oceanic mixing as well as 
     the rate of gas exchange between ocean surface and atmosphere. The 
     coverage of 14C measurements from SAVE is much denser than that of its 
     predecessor, GEOSECS, and can provide a much better base upon which 
     future C02 studies can build. It also provides a view at the evolution 
     of bomb 14C distribution over the last decade since GEOSECS, as several 
     GEOSECS stations were reoccupied during SAVE.
     
     
     
     II.  CRUISE DESCRIPTIONS
     
     The SAVE expedition consisted of two cruises subdivided into six legs.
     
     A.  YEAR 1
     
     The first leg aboard the R/V Knorr, began 23 November 1987 from Recife, 
     Brazil. The Knorr crossed the Atlantic Ocean on a northeasterly course 
     and arrived into Abidjan, Ivory Coast on 13 December 1987. A total of 
     121 radiocarbon samples was collected from ten large volume stations. 
     During a deep Gerard cast on station 32, all barrels were lost when the 
     winch cable snapped. Two spare Gerard barrels were used during the 
     remainder of Leg 1, which limited sample collection to the upper 1000m 
     of depth.
     
     The Knorr departed Abidjan on 18 December 1987, heading southwest and 
     arrived in Rio de Janeiro, Brazil on 23 January 1988. During Leg 2, 163 
     14C samples were collected from 21 large volume stations. With the 
     exceptions of stations 95 and 99, where deep samples were collected from 
     the core of the Antarctic Bottom Water and North Atlantic Deep Water, 
     maximum sample depth was 1000m.
     
     On Leg 3, once again armed with full complement of Gerard barrels, the 
     expedition set out on 28 January 1988, traveled southeast to about OW 
     then heading north back to Abidjan. Before the cruise ended on 7 March 
     1988, 349 radiocarbon samples were taken at 30 large volume stations.
     
     
     B.  YEAR 2
     
     The second year of SAVE began with departure of the R/V Melville from 
     Punta Arenas, Chile on 7 December 1988. She crossed the South Atlantic 
     Ocean along 47S to 20W, headed northeast to 30S before steaming due 
     east to Capetown, South Africa, arriving on 15 January 1989. During Leg 
     4, 299 radiocarbon samples were collected from 27 large volume stations.
     
     Leg 5 cruise departed Capetown on 23 January 1989. The cruise track 
     consisted of two meridional sections: the first traversing from 24W 
     south to South Georgia Island; the second section going north along 
     41W. A small northwest portion of the track heading toward Montevideo, 
     Uruguay ended on March 8, 1989. A total of 173 14C samples was taken on 
     20 stations.
     
     The remainder of the cruise was a meridional section called HYDROS, Leg 
     4, which ran north from SAVE station 237 to the equator along 25W. 
     During this leg, 107 radiocarbon samples were collected from eight 
     stations. The program ended 19 April 1989. The table below summarizes 
     the sample collection and measurement.
       

                                    | # Radiocarbon Samples
                                    | ---------------------
                         Cruise Leg | Collected | Measured
                         ---------- | --------- | --------
                             SAVE 1 |    121    |    117
                                  2 |    163    |    111
                                  3 |    349    |    296
                                  4 |    299    |    256
                                  5 |    173    |    159
                           HYDROS 4 |    107    |    100
                          --------- | --------- | --------
                              TOTAL |  1,212    |  1,039
     
     
     C.  SAMPLES STILL AVAILABLE FOR ANALYSIS
     
     Although most of the samples collected during SAVE have been analyzed, 
     139 samples are still unmeasured and are archived at our laboratory. 
     Stations not yet analyzed are presented as tables located in the last 
     section of this report, starting on page 72. We hope that the sample 
     selection by various investigators and us has covered the major and 
     relevant ocean features explored during the two years of SAVE. In the 
     event that some questions remain that could be answered with additional 
     analyses, we intend to store the remaining samples for a few more years.
     
     
     
     III.  TECHNICAL PROCEDURES
     
     A.  SAMPLING
     
     Water samples were collected on board ship using 270 liter stainless 
     steel Gerard barrels. Shipboard extraction of C02 was performed by 
     acidifying 200 liters of seawater with 50ml of 95% sulfuric acid, and 
     bubbling through an inert C02-free gas. The released C02 was then 
     stripped from the carrier gas and re-dissolved into a 450ml bottle of 4N 
     sodium hydroxide (NaOH). The sample bottles were then shipped to the 
     Tritium Laboratory for measurement. Resulting yield, under favorable 
     conditions, was about 9 lit-atm of C02 or 95 - 98% of the total dissolved 
     C02 in the sample.
     
     
     B. PREPARATION OF SAMPLING GAS
     
     In the laboratory, C02 was released from the NaOH solution by adding 
     phosphoric acid. Nitrogen gas, the carrier, transferred C02 and any 
     other evolved gases to collection traps maintained at -196C by liquid 
     nitrogen. After pumping on the solid C02, this gas was then passed 
     through a purification system consisting of a series of cold traps to 
     remove water vapor, and two copper-silver ovens to remove gaseous 
     electronegative impurities, mainly chlorine and oxygen. Remaining 
     impurities were removed by pumping on condensed C02 at a temperature of 
     -196C. It is our experience that yields are about 99.7% of the total 
     C02 contained in the NaOH solution. Occasionally, yields were less than 
     optimal for counting in the large radiocarbon counters. These samples 
     were saved when possible by counting in a smaller counter for twice the 
     length of time required for a normal size sample.
     
     At this point, a small aliquot of purified gas was removed for 
     massspectrometric delta-13C analysis. The remaining gas was stored in a 
     stainless steel high pressure cylinder for 14 to 21 days before counting 
     to allow any radon to decay (half-life is 4 days). The radon apparently 
     originated from the phosphoric acid, and occasionally from the glass of 
     the NaOH bottles.
     
     Below follows a description of our standard 14C measurement technique 
     and special modification for this project.
     
     
     C. COUNTING
     
     We have four 2.5 liter and one 1 liter low-level gas proportional 
     counting tubes for 14C, using C02 gas samples. The counters are shielded 
     by 2.5 cm of selected lead, a ring of anti-coincidence Geiger counters, 
     10cm of paraffin wax, boric acid and/or borated polyethylene, and at 
     least 20 cm of iron, plus the walls and ceiling of the building. The 
     counter is filled with the sample to a working pressure of 45 psi. The 
     proper operating voltage, dependent on temperature and pressure in the 
     counter, is adjusted to produce the most efficient and stable 14C 
     detection. This is done by an external radioactive source, usually 60-
     CO. Gas amplification is continually monitored by the distribution of 
     meson counts in selected energy channels. The occurrence of radon is 
     monitored in a separate channel with each counter. Each sample is 
     counted for at least two separate periods of about 20 hours each, in 
     different counters, with an interim waiting time of at least 7 days. 
     Inconsistency between the two counts prompts an additional measurement 
     in a third counter. For the short samples in this series, two counters 
     were temporarily standardized to work at low pressure. These samples 
     were counted for a total of 4 to 6 days.
     
     
     D. BACKGROUND AND STANDARDS
     
     Background count rates, typically 3.5 cpm, are determined weekly by 
     measuring 14C-free C02 gas. The standard material for 14C measurements 
     is the NBS oxalic acid standard, RM49 and SRM4990C, for radiocarbon 
     dating. The C02 prepared from this standard is counted for two days 
     every week in each counter, to determine counting efficiency; typical 
     count rate for an ocean surface sample is 43 cpm above background.
     
     
     E. UPDATE
     
     Periodically, usually every five weeks, all measurements in all counters 
     for the preceding time period are recomputed, statistical tests are 
     applied, and results scrutinized for flaw in quality of sample counts 
     and stability of efficiency and background. This includes all measurements 
     of standards, unknown and backgrounds. Only after this step is the 
     measurement result considered final.

     Contribution from minute quantities of C02 in the original NaOH solutions 
     is measured for each batch of NaOH and appropriate corrections have been 
     applied.
     
     
     
     IV.  NOTES ON SCALES
     
     The measurement results in the ratio, r, between the measured specific 
     activity of the sample C02 and that Of C02 prepared from the NBS 
     standard. The activity value of the standard is corrected to a 
     hypothetical delta-13C value of -19 and age-corrected from today back 
     to AD1950, all according to international agreement. DELTA-14C is the 
     deviation, in  (per mil), from unity, of the activity ratio, isotope-
     corrected to a sample delta-13C value of -25 Normally there is very 
     little ( 0.3) isotope separation in our preparation procedure. Within 
     these limits, our delta-13C values represent the state of isotope fraction-
     ation of the original seawater C02. According to this convention, each of 
     our reported DELTA-14C values is, however, normalized to the delta value it 
     would have if its delta-13C changed to -25, noting that the change is 
     equal to twice the change in 13C . Note that the mass of 14C is always 
     proportional to the r-value, not to DELTA-14C See Appendix 1.
     
     Dr. Minze Stuiver at the Quaternary Lab, University of Washington measured   
     the delta-13C values for this project by precision mass-spectrometry.
     
     For further explanation of these features, and information on standards, 
     cf. preface to each issue of Radiocarbon, and papers by Broecker and 
     Olson (1), Stuiver and Robinson (2) and by Stuiver and Polach (3). Also 
     refer to Appendix.
     
     
     
     V.  ACCURACY AND ERRORS
     
     Errors for delta-14C are not listed in the tables. For a normal size 
     sample the errors are 3.0 to 3.5 for precision and 3.5 to 4.0 for 
     accuracy, including all conceivable uncertainties. The small samples, 
     due to the very long counting times should be about as good.
     
     
     
     VI. HYDROGRAPHIC DATA
     
     The hydrographic data were supplied by the Ocean Data Facility (ODF), 
     Scripps Institution of Oceanography. Total C02 data were supplied by 
     Taro Takahashi, Lamont Doherty Geological Observatory at Columbia 
     University. They are presented in mol/kg.
     
     We calculated potential temperature from in situ temperature, pressure, 
     and salinity by the equations of Bryden (4). The density (sigma-theta) 
     values were calculated according to the International one-atmosphere 
     equation of state of seawater according to Millero and Poisson (5), 
     which generates absolute densities in units of kg/m3.  For serious use 
     of the hydrographic, data, please refer to the Scripps Institution of 
     Oceanography SAVE Data Reports; S.I.0. Reference 92-9, 92-10 and 92-12. 
     For total C02 data please contact Taro Takahashi.
     
     
     
     VII.  COMMENTS TO FIGURES AND TABLES
     
     A.  SECTIONS
     
     Radiocarbon is expressed as DELTA-14C  The horizontal scale distance is
     given in kilometers with accompanying latitudes or longitudes. The 
     vertical depth scale is in meters. Dots indicate measured samples. Due 
     to scant data coverage in several areas, some subjectivity enters in 
     drawing the isopleths.
     
     
     B.  PROFILES
     
     Radiocarbon is plotted as A14C  versus depth in meters. The bottom 
     depth is marked by a horizontal line when it falls inside graph limits. 
     Occasionally, some of the data were not reliable and are designated by 
     "++" or small letters. Explanations are found in the tables of data.
     
     
     C. TABLES
     
     Positions are stated in degrees and minutes. SMPL# is the cast and 
     Niskin bottle number. GER represents the cast and Gerard barrel number. 
     DC14 is DELTA-14C  and dC13 is delta-13C  TC02 is total dissolved 
     carbonate in mol/kg. All collected sample's are presented in the 
     tables. Those samples marked with an asterisk, * are still available for 
     analysis.
     
     
     
     VIII. REFERENCES
     
     Broeker, W.S. , and E.A. Olson, 1961. Lamont radiocarbon measurements VIII. 
         Radiocarbon, 3, 176-274.
     
     Stuiver, M. , and W.S. Robinson, 1974. University of Washington GEOSECS 
         North Atlantic carbon-14 results. Earth Planet, Sci. Lett., 23, 87-90.
     
     Stuiver, M. , and H.A. Polach, 1977. Discussion reporting of 14 C data. 
         Radiocarbon, 19, (3), 355-363.
     
     Bryden, H.L., 1973. New polynomials for thermal expansion, adiabatic 
         temperature gradient and potential temperature of sea water. Deep-Sea 
         Res., 20, 401-408.
     
     Millero, F.J. and A. Poisson, 1981. International one-atmosphere equation 
         of state of seawater. Deep-Sea Res., 28, (6A), 625-629.
     
     
     
     
                        APPENDIX  (Revised August 15, 1992)
     

         ON THE MEANING AND USE OF DELTA-14C AND DELTA-14C IN OCEANOGRAPHY
                                         by
                                  H. Gte stlund
                   Tritium Laboratory, RSMAS, University of Miami
     
     
     Summary  OOPS! Don't use delta-14C for calculating quantity of 14C.
     
     
     ARGUMENT delta
     
     Beta counting of 14C produces results in form of count rates, which can 
     be converted to the relative specific activity r of the sample defined 
     by
     
        r = Asx/Ast = Isx/Ist                                              (1)
     
     where Ast is the adjusted specific activity of the NBS oxalic acid 14C 
     standard, 13.56 dpm/g of carbon, and Asx is the specific activity of the 
     sample in dpm/g.  By applying the decay rate of 14C this ratio can also be 
     expressed in isotope 14C/Ctot-abundance ratios I, where Ist is 1.176 - 10-12. 
     Often a 'per mil deviation', delta-14C is calculated according to
     
        delta-14C = 1000  (r - 1)                                         (2)
     
     See Remark.
     
     Assuming that isotope fractionation is negligible during sample 
     preparation, the r-value (and thereby the delta-14C) is the proper 
     parameter to use for computing the absolute, true quantity of 14C as 
     number of atoms or moles. Thus the amount of 14C in moles, in a kg of 
     seawater or air is
     
                             -12
        SIGMA-14C = 1.176 - 10    r  SIGMA                               (3)
     
     where SIGMA-C is the absolute assay of carbon in moles/kg.  Mass inventories 
     of 14C, as well as macroscopic mixing and transports by currents and 
     turbulent diffusion call for the use of Eq 3.  If there is fractionation 
     during collection and processing of a sample, the true, original r-value 
     can be calculated from the sample r-value if delta-13C data are available 
     for both.  By experience the standard ship-board C02 extraction from 
     seawater and laboratory processing cause isotope shifts that are less 
     than 0.5 and thus insignificant.
     
     
     ARGUMENT DELTA: 
     
     By (an unfortunate) convention environmental 14C data are usually 
     expressed as DELTA-14C or R according to
     
        DELTA-14C = delta-14C - 2 (delta-13C + 25)  (1 + 0.001delta-14C)  (4)
        R = 1 + 0. 001.DELTA-14C                                           (5)
     
     These equations describe what the 14C/Ctot isotope ratio would be if a
     hypothetical chemical fractionation  process brings the delta-13C value 
     from its actual value to -25 per mil.
     
     The use of the DELTA-14C and R is a carry-over from the radiocarbon 
     dating procedures, where isotope fractionation in the biological cycle 
     necessitates this correction to allow calculation of best 'radiocarbon 
     age' of a sample, most often organic material. The delta-13C reference 
     value -25 was originally chosen as standard value, being typical for 
     terrestrial wood, first used for 14C standard material.
     
     In geochemical considerations, conversion to DELTA-14C is needed for 
     calculations of "mummy" ages and for the proper handling of chemical 
     equilibria, rate of chemical reactions and phase transfers. Examples:
     
          Mummy age = (-ln R) / lambda           years before AD 1950.
     
                                           -1
     where lambda is 14C decay rate in years
     
     In air-sea exchange of 14C02, assume Pair and Pdia are partial pressures 
     of atmospheric and dissolved C02 and Rair and Rdis the isotope adjusted 
     R-values according to Eq. 5, then there should be chemical equilibrium 
     (no net transport) of 14C02 if
     
          Pair Rair - Pdis Rdis
     
     
     
     CONCLUSION: 
     
     The r-values (delta-14C) are needed for use in the calculation of mass 
     of 14C. If only DELTA-14C values are available, this is accomplished by 
     solving for r in the equations 5,4 and 2 above and putting the value into 
     Eq 3.  With some approximation:
     
          Oceanic dissolved C02     delta-13C =   0.0  r = 1.050 R
          Atmospheric C02           delta-13C = - 8.5  r = 1.033 R
          Wood (cellulose)          delta-13C = -25    r = 1.000 R
     
     The factors in column 3, above express the errors obtained in 14C 
     inventories if DELTA-14C, or R, is used instead of delta-14C, or r.
     
     When one compares 14C in various parts of the ocean, a systematic error 
     of 5% may be insignificant. Also measured transfer coefficients have 
     larger uncertainties than 5%. However, include a production term for 14C 
     (cosmic, industrial), or the atmospheric inventory, and there is cause 
     for concern.
     
     
     
     REMARK
     
     In the exhaustive, maybe exhausting, paper by Stuiver and Polach
     (1977) delt-14C is indeed defined accurately and properly, with age
     corrections of standard material activity to AD 1950, and for the
     time elapsed between collection and measurement of the unknown
     sample. It is the first equation (un-numbered) on pg. 361 in that
     paper. The activity and isotope ratio values of the NBS oxalic acid
     standard are listed in several papers, among them one by Stuiver et
     al, (1981), viz pg. 208. The inventory equation on that page should
     use delta-14C , not DELTA-14C.
     
     
     
     POSTSCRIPT:
     
     This error was pointed out in a recent paper by Bard et al, (1988), and 
     is discussed by stlund and Rooth (1990), as well as by Lassey (1989). 
     In this pioneering paper on global 14C, Craig (1957), correctly used the 
     unadjusted r-values, and so did Kuc (1986 and 1987) on atmospheric 14C 
     inventories. Most often, however, DELTA-14C is erroneously used for 
     absolute quantities of 14C.
     
     __________________________________________________________________________
     __________________________________________________________________________

       FIRST PRESENTED AT THE MODELING WORKSHOP, SEATTLE, WA - AUGUST, 1989
     __________________________________________________________________________     
     __________________________________________________________________________     


     REFERENCES:
     
     Bard, E., M. Arnold, H.G. stlund, P. Maurice, P. Monfray and J-C 
          Duplessy.  Penetration of bomb radiocarbon in the tropical Indian 
          Ocean measured by means of accelerator mass spectrometry, Earth and 
          Planet. Sci. Lett., 87, 379-389, 1988, viz pg. 380.
     
     Craig, H. The Natural Distribution of Radiocarbon and the Exchange Time 
          of Carbon Dioxide between Atmosphere and Sea, Tellus, 9(1), 1-17, 1957.
     
     Kuc, T. Carbon isotopes in atmospheric C02 Of the Krakow Region: A two-
          year record, Radiocarbon, 28, 649-654, 1986.
     
     Kuc, T. 14C traced in Krakow after the Chernobyl accident, Radiocarbon, 
          29, 319-322, 1987.
     
     Lassey, K.R., M.R. Manning and B.J. O'Brien. An Overview of oceanic 
          radiocarbon, its inventory and dynamics, Aquatic Sciences, 3, 117-146, 
          1990.
          
     stlund, H.G. and C.G.H. Rooth. The North Atlantic tritium and 
          radiocarbon transients, 1972-1983. J. Geophys. Res., 95, 20,147-20,165, 
          1990.
          
     Stuiver, M. and H.A. Polach. Discussion Reporting of 14C Data, 
          Radiocarbon, 19, 355-363, 1977.
     
     Stuiver, M., H.G. stlund and T.A. McConnaughey. GEOSECS Atlantic and 
          Pacific 14C Distribution in Carbon Cycle Modeling, Wiley and Sons, 
          1981, edited by Bert Bolin.
          
     


                                                            A16S (SAVE 5)  1989
      __________________________________________________________________________
      __________________________________________________________________________


     CCHDO-WHPO DATA PROCESSING NOTES

     DATE      CONTACT      DATA TYPE  DATA STATUS SUMMARY
     --------  -----------  ---------  -----------------------------------------
     12/14/98  Key          DELC14     Key has data

     01/11/99  Smethie      CTD/BTL    Data are public

     04/16/99  Jenkins      He/Tr      Projected Submission Date: 1999.09.15 
               disk crash/must reprocess

     06/03/99  Diggs        CTD        CTD data are still with the PI. 

     06/04/99  Smethie      CTD        Data avail. at ODF/SIO

     06/07/99  Smethie      CTD        Data are Public
               I thought you had all the SAVE and you certainly have my 
               permission to obtain the CTD data.  It is my understanding as 
               you indicate in your e-mail that it is public

     03/07/00  Talley       CTD/BTL    Data are Public; ctd data should 
               be on website

     05/31/00  Huynh        DOC        Website Updated; pdf, txt versions 
               online

     06/16/00  Talley       CTD        Submitted; not woce formatted

     07/07/00  Anderson     CTD/SUM    Data Reformatted
               Reformatted .sum file.
               Reformatted CTD files, added correct headers.
               Used 2 for all QUALT codes.  
                * Station 279 did not have oxygen, so used quality flag of 9.  

     07/10/00  Bartolacci   SUM        Updated file online
               I have replaced the current sumfile with the newly reformatted 
                    sumfile (by SAnderson) and updated all table references

     07/10/00  Bartolacci   CTD        Reformatted file online
               I have linked the newly reformatted CTD file (reformatted by S. 
               Anderson) and updated all table references.

     12/11/00  Uribe        DOC        Submitted
               File contained here is a CRUISE SUMMARY and NOT sumfile; 
                 Documentation is online.
               Files were found in incoming directory under whp_reports. 
               This directory was zipped, files were separated and placed 
                 under proper cruise. All of them are sum files.
               Received 1997 August 15th.


     DATE      CONTACT      DATA TYPE  DATA STATUS SUMMARY
     --------  -----------  ---------  -----------------------------------------
     04/03/01  Diggs        CFCs       Submitted
               CFC data submitted by Peter Salameh @ SIO. Placed files in 
               data/onetime/ atlantic/a16/ onetime

     04/11/01  Muus         CFCs/SUM   CFC Data Merged; New SUM file generated
               Notes file for A16S modification and final CFC merging. 
               SAVE Leg5/HYDROS Leg 3 R/V MELVILLE April 11, 2001 D. Muus
                 1. Generated new SUMMARY file from final SIO/ODF data. Now 
                    has Uncorrected as well as Corrected Bottom Depths,    
                    corrected EVENT CODEs, NAV, Height ABOVE BOTTOM, WIRE OUT, 
                    MAX PRESS, NO. OF BOTTLES, complete parameter numbers from 
                    Sample Log Sheets and COMMENTS from ODF Station and Cast 
                    Description. Neodynium was not included since it does not 
                    have a parameter number. Particulates were not included 
                    since the documentation does not say whether they were 
                    parameter number 40 or 41 (or both). 
                 2. Generated new SEA file from final SIO/ODF data. Now has 
                    BTLNBRs, complete CTDSAL and more decimal places in data. 
                    ODF did not include CTDOXY with bottle data in pre-woce 
                    cruises so it is not available for this report. Oxygen is 
                    included with the CTD data. 
                 3. Merged final CFC data received from Peter Salameh April 3, 
                      2001/usr/export/html-public/data/onetime/atlantic/a16/
                        original/A16_SAVE_CFC/save5.txt 
                    into the new SEA file, replacing the shipboard CFCs in the 
                    ODF data. 

     04/16/01  Muus         CFCs       Reformatted by WHPO
               The modified a16c and a16s data are in ~dave/SDIGGS/A16.  I 
                 was wrong in my April 3rd message assuming the .SEA files 
                 were from ODF. They look more like they were generated from 
                 .sd2 files.  I redid everything from the final ODF data: .SUM 
                 files, .SEA files for rosette and .SEA files for large volume 
                 samplers.  Freons were collected from the piggyback Niskins 
                 on many of the Large Volume casts.  Many of the CFCs have 
                 quality codes of 6 meaning they are averages of replicate 
                 samples. The WOCE instructions say the details on the 
                 replicates should be in the documentation. I haven't seen any 
                 such documentation, could it be in the original CFC data 
                 directory in "a16_save_cfc.mail"?  The read permission is 
                 'owner only'.
               We do not have any of the actual large volume data 
                 (c14, argon-39, krypton, radium 228 & 226). The new files 
                 included them in the .SUM parameters but do not have any 
                 headers in the .SEA files.
               Successfully ran sumchk and wocecvt.
               Please let me know if you have any questions or need further 
                 clarification.    


     DATE      CONTACT      DATA TYPE  DATA STATUS SUMMARY
     --------  -----------  ---------  -----------------------------------------
     06/20/01  Uribe        BTL        Website Updated; Exchange File Online
                 Bottle file in exchange format has been linked to website.

     06/21/01  Uribe        CTD/BTL    Website Updated; new exchange files
               The exchange bottle file name in directory and index file 
               was modified to lower case.
               CTD exchange files were put online.

     08/02/01  Key          DELC14     Website Updated; PI names corrected 
               The PIs for C14 during SAVE/HYDROS were Broecker/Ostlund. 
               The summary table shows No Data for A16C or A16S. I can 
               provide copies of the LV files for all of SAVE/HYDROS if you 
               do not have. I do not have Jenkin's (not Smethie) H3/He3 data 
               for these cruises.

     08/27/01  Swift        He/Tr      HE/TR data requested by J Swift
               WHPO records indicate he/tr data not yet submitted. Request for 
               earliest possible submission sent to Bill Jenkins.

     09/17/01  Diggs        CFCs/LV    New hyd/sum/LV & exchange files online
               Replaced both the SUM and BOTTLE files online with the ones 
               with CFC values (Muus 20010416). Also placed LVS file online, 
               produced EXCHANGE file and placed on website. EXCHANGE file 
               verified w/ JOA v3.0.

     11/12/01  Key          BTL/SUM    BTL and SUM submitted, see note:
               I uploaded the SAVE+HYDROS LV files today using your form. 
               Note that a bottle number of "99" is a surface sample 
               obtained without using a Gerard barrel. The file I sent does 
               NOT have the piggyback niskin bottles. The only way I have 
               that information is in a merged ascii file with "everything". 
               This merged file does not have flags and is closer to the 
               original files sent out by ODF + merged data I recieved from 
               individual investigators. I have attached a copy of this file 
               "just in case". The attached file is in an shortened format, 
               but your guys won't have any trouble doing a reformat.


     DATE      CONTACT      DATA TYPE  DATA STATUS SUMMARY
     --------  -----------  ---------  -----------------------------------------
     11/19/01  Key          BTL        Large Volume submitted, not DQE'd
               This is information regarding line: SAVE 1-5; HYDROS-4
                 ExpoCode: 
                 Cruise Date:   1987/11/23 - 1989/04/19
                 From:          KEY, ROBERT
                 Email address: key@princeton.edu
                 Institution:   PRINCETON
                 Country:       USA
                 The file:      SAVE.dat - 209411 bytes
                 has been saved as: 
                                20011112.075818_KEY_SAVE1_5;HYDROS_4_SAVE.dat
                 in the directory:  
                                20011112.075818_KEY_SAVE1_5;HYDROS_4
                 The data disposition is:  
                                Public  
                 The bottle file has the following parameters: 
                                CTDPRS, REVTMP, SALNTY, OXYGEN, SILCAT, NITRAT
                                NITRIT, PHSPHT, C14,    C14ERR, TCARBN, ALKALI
                 The file format is:
                                Comma Separated Values 
                 The archive type is:  
                                NONE - Individual File 
                 The data type(s) is:
                                Summary (navigation)
                                Bottle Data (hyd)
                 The file contains these water sample identifiers:
                                Cast Number (CASTNO)
                                Station Number (STATNO)
                                Bottle Number (BTLNBR)
                 KEY, ROBERT would like the following action(s) taken on the data:  
                                Place Data Online
                 Any additional notes are: 
                                WOCE flags have been assigned and are included, 
                                however, th  QC was NOT thorough, especially with 
                                respect to routine hydro data.

     12/06/01  Key          DELC14     Data QC'd to WOCE standards
               The primary ref. for the SAVE/HYDROS C14 data is:

                                    S.A.V.E. Radiocarbon
                      South Atlantic Ventilation Experiment 1987-1989
                           Tritium Laboratory Data Report No. 18
                                H. gote Ostlund and C. Grall
                                         Univ. OF Miami
                    Rosenstiel School of Marine and Atmospheric Science
                                       Miami, FL 33149
                                         Sept. 1992
                                            84pp

               I will try to do a more complete QC of SAVE by the end of the 
               year, but this should only amount to a footnote saying that 
               the data have been QCed to WOCE standards.


     DATE      CONTACT      DATA TYPE  DATA STATUS SUMMARY
     --------  -----------  ---------  -----------------------------------------
     12/20/01  Uribe        CTD        Website Updated; Exchange file online
               CTD has been converted to exchange using the new code and 
               put online.

     12/20/01  Hajrasuliha  CTD        Data consistency check done

     07/10/02  Huynh        DOC        Website Update; PDF & TXT cruise 
               reports online

     03/20/03  Kozyr        TCO2/PCO2  Submitted
               I noticed that the carbon data for A16S (R/V MELVILLE CR 
               SAVE-5/HYDROS-3 WHP-ID A16S  23 JAN 1989 - 8 MAR 1989  
               20010417WHPOSIODM) are missing in WHPO bottle data file. I 
               have put the data file with TCO2 and pCO2 (and pCO2TMP) 
               values into WHPO ftp area.

     04/16/03  Anderson     TCO2/PCO2  Data merged into online BTL file
               Merged carbon data into online file. 
               Made new exchange file, put files online.
                 Notes on a16s carbon merging:

               April 16, 2003
               A. Kozyr noted that the carbon data for a16s was not in the 
                 online file. (See e-mail above)
               Since the file he sent only had station number and bottle 
                 number to use for merging, I retrieved the a16s carbon data 
                 from his web site.
                  Merged TCARBN, PCO2, and PCO2TMP into the online file 
                                   20010412WHPOSIODM.
                  Copied QUALT1 flags to QUALT2 flags.
                  Changed the missing data code for TCARBN and PCO2 from -999.9 
                   to -9.0 and for PCO2TMP from -999.90 to -9.00.
                  Made new exchange file, and put files online.
 
     09/28/04  Kappa        DOC        PDF & Text Cruise reports expanded/updated
               Additions to both versions (PDF and Text):
                 Final ODF-SIO Data Report which includes:
                   Bottle Data Collection, Analyses and Processing
                    Salinity, Oxygen, Nutrients
                   CTD Data Collection, Analyses and Processing
                   References
                   CTD Processing Notes
                   Bottle Data Processing Notes
                   List of Participants
                 Radiocarbon report by H. Gte stlund and Charlene Grall
                 CCHDO-WHPO cruise summary page (page 1)
                 These CCHDO-WHPO Data Processing Notes
               
               Changes to PDF version only:
                 Added standard "WOCE" outline (page 2) with links to text 
                 Updated CCHDO-WHPO station plot with improved clarity
                 Added station track from author's original report
                 Added scatter plots (nutrients)
                 Added figures for radiocarbon report
 
