          A.  CRUISE NARRATIVE: A16N
              (updated April, 2004)
          
          A.1  HIGHLIGHTS 
          
                                  WHP CRUISE SUMMARY INFORMATION
          
                          WOCE section designation  A16N
                 Expedition designation (ExpoCode)  32OC202_1
           Chief Scientists and their affiliations  MICHAEL MCCARTNEY/WHOI
                                                    LYNNE D. TALLEY/SIO
                                                    MIZUKI TSUCHIYA/SIO 
          
                                             Dates  1988.07.23 - 1988.09.01
                                              Ship  RV OCEANUS
                                     Ports of call  Reykjavik, Iceland to Funchal, Madeira
                                                    
                                Number of stations  133
                                                               6319.8'N
                   Stations' Geographic boundaries  2901.1'W             1958.4'W
                                                               0000.3'N
                      Floats and drifters deployed  none
                    Moorings deployed or recovered  none
          
                              Contributing Authors  John Bullister
                                                    
                                                    
                                                    
                                                   
          
          NOTE: For full text and figures, please refer to SIO Reference 91-16 (May 1991)
          
                                      Data Report Prepared by:
                                    OCEANOGRAPHIC DATA FACILITY
                                Scripps Institution of Oceanography
                                University of California, San Diego
          
          
                     Sponsored by National Science Foundation Grant OCE 86-14486
          
          
          
          Table of Contents 
          
          1. OVERVIEW
          2. NISKIN BOTTLE DATA COLLECTION, ANALYSES, AND PROCESSING
          3. CTD DATA COLLECTION, ANALYSES, AND PROCESSING
          4. DATA TABLES AND PLOTS
          5. ACKNOWLEDGEMENTS
          6. REFERENCES
          7. CHLOROFLUOROCARBON ANALYSIS METHODS
          
             APPENDIX A:  CTD PROCESSING NOTES
             APPENDIX B: REMARKS FOR DELETED OR MISSING SAMPLES
          
             CRUISE TRACK        (see PDF version)
             STATION AND CAST DESCRIPTIONS
             PERSONNEL LIST
             CTD AND BOTTLE DATA (see SIO/ODF publication*)
             VERTICAL SECTIONS   (see PDF version)
          
          
                         * SIO Reference 91-16      ODF Publication No. 229
          
          
          
          1.  OVERVIEW 
          
          The first leg of OCEANUS 202 commenced on July 23, 1988 with departure from 
          Reykjavik, Iceland at 10:12 A.M. GMT. The first station was located just 
          offshore of southern Iceland at 6319.7'N, 1959.9'W to a depth of 195 meters. 
          The first leg ended at Station 65 on August 6, 1988 at 3318'N, 2137'W. After a 
          brief port stop in Funchal, Madeira, work resumed with a reoccupation of Station 
          65 (at 3251'N, 2120'W) on August 11, 1988, and continued through Station 129 
          on August 27, 1988.
          
          Station spacing was generally 30 nautical miles from Stations 1 to 71 with the 
          exception of reduced spacing over steep topography. Spacing from Stations 72 
          to 112 was about 46 nautical miles. Spacing was the reduced across the equator. 
          Stations 61, 62, 63, and 65 were repeated in order to complete the patchy 
          vertical sampling resulting from a pylon problem, discussed below.
          
          Each station consisted of a CTD/rosette cast to within 10 meters of the ocean 
          bottom, with the exception of the repeated casts at Stations 61, 62, 63 and 65 
          which were 1000 to 1500 meters. The rosette carried 24 4-liter bottles.
          
          Ship navigation was either Loran-C (to about 50N), GPS or transit-omega, the 
          latter used only when GPS fixes were insufficient. Navigation was recorded on a 
          SAIL loop and was networked to ODF's computer system where it was used for 
          station positions and bathymetry. Bathymetry was recorded every five minutes 
          from the OCEANUS' PGR.
          
          An acoustic doppler current profiler (ADCP) was operated throughout the first 
          leg by Frederick Bingham of SIO. Water in the transducer well resulted in 
          termination of ADCP acquisition on August 21. Scripps Shipboard Technical 
          Support/Oceanographic Data Facility (ODF)ls/Neil Brown Mark 3 CTD #2, rosette 
          frame and General Oceanics pylon were used throughout. A set of new 2.5 liter 
          Niskin bottles were provided by John Bullister of WHOI; they were designed to 
          minimize 0-ring contact with the sample water so that CFC samples would be as 
          uncontaminated as those drawn from 10-liter bottles.
          
          Bob Williams and Forrest Mansir of ODF provided the at-sea support of the ODF 
          equipment. CTD data were acquired on an ODF deck unit and Integrated 
          Solutions computer, audio backups were recorded on video tape. Frank 
          Delahoyde of ODF provided the software support and shipboard CTD data 
          processing. Salinity samples were analyzed on a Guildline autosalinometer by 
          Forrest Mansir and Leonard Lopez of ODF. Oxygen samples were analyzed on 
          the ODF's titration rig by Ron Patrick of ODF and Bob Williams. Nutrient samples 
          were analyzed for NO3 NO2 PO4 and SiO3 on an Alpkem Rapid Flow Analyzer, by 
          Joe Jennings from Oregon State University. The OSU and ODF computer 
          systems were networked for data transfer and thus permitted complete 
          preliminary data reports at various points during the cruise.
          
          CFC samples were collected by John Bullister, Scott Doney, and Chris Johnston 
          and were processed at sea. Tritium/helium samples were collected by Scott 
          Doney for later processing by Bill Jenkins' group at WHOI. Because of the water 
          demands when tritium/helium and CFC samples were both being drawn, oxygen 
          samples were drawn from the copper helium tube rinse water.
          
          Preliminary CTD data processing was carried out at sea during and after the 
          casts. Subsets of CTD data comparable to the water samples were provided to 
          the bottle data files immediately after each station in order to facilitate 
          examination and quality control of the bottle data as the laboratory analyses 
          were completed. It was discovered relatively quickly at sea that one of the ODF 
          pylons was occasionally double-tripping and then skipping trips. This and other 
          tripping problems were persistent on this expedition, perhaps partly because of 
          the high profiling speeds and attendant stress on the terminations and slip 
          rings. The effects on the final data are documented later in this report. 
          (Appendices A and B).
          
          
          
          2.  NISKIN BOTTLE DATA COLLECTION, ANALYSES, AND PROCESSING
          
          After each rosette cast was brought on board, analysts drew water samples from 
          each sampler for various parameters and recorded the water sample bottle 
          assignment along with the Niskin sampler it was drawn from. STS/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. 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 (for example in a plot comparison), 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.)
          
          Problems with the rosette pylon and electrical harness caused tripping problems. 
          In most cases, ODF reports CTD data from scheduled bottle trip levels even 
          when there might not have been a water sampler closure. This has been done to 
          preserve a well-sampled discrete profile and hence better accommodate 
          investigators who prefer using bottle data files exclusively. Other extra CTD 
          levels were extracted from CTD data for purposes of reporting data at the 
          deepest point. Because there is only a small separation between the deepest 
          bottle and the deepest CTD level, we advise caution in use of this bottommost 
          level if the data are interpolated. The repeated stations 61, 62, 63 and 65 
          should not be merged as unacceptable offsets in most parameters results.
          
          
          2.1.  PRESSURE AND TEMPERATURE
          
          All pressures and temperatures for the Niskin bottle data tabulations for 
          Oceanus Cruise 202 were extracted from the processed CTD data, usually those 
          from the corrected 10-second average bottle trip files collected during the up 
          cast. (See below.) 
          
          
          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, 1981) 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 (such as experienced in 
          the van borrowed for this expedition), salinities from bottle samples have a 
          lower true precision under field conditions than in the laboratory. There was a 
          problem with temperature control in the van where the salinity analysis 
          occurred. Some of the missing bottle salinity values are attributed to this 
          problems. 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 Appendix B).
          
          
          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 1 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 1 to 3 stations. Several standards were made up and compared to 
          assure that the results were reproducible, and to preclude basing the entire 
          cruise on one standard, with the possibility of a weighing error. A correction 
          (-0.014 ml/l) was made for the mount 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 quality of the KIO3 is the ultimate limitation on the accuracy of this 
          methodology. The assay of the finest quality KIO3 available to ODF is 100%, 
          0.05%. The true limit in the quality of the bottle oxygen data probably 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%.
          
          
          2.4.   NUTRIENTS
          
          The following section was contributed by Lou Gordon of Oregon State University. 
          Nutrient analyses were performed by Joe C. Jennings, Jr. and Lee Goodell of 
          Oregon State University using an Alpkem Corp. Rapid Flow Analyzer, Model 
          RFA-300 (RFA). The methods for silicic acid, nitrate plus nitrite and nitrite 
          were those given in the Alpkem manual (Alpkem, 1987). The method for phosphate 
          was an adaptation of OSU's hydrazine reduction method for the AutoAnalyzer-II 
          (Atlas et al., 1971). The adaptation consisted of scaling reagent concentrations 
          and pump tube sizes to duplicate final concentrations of reagents in the sample 
          stream used with OSU's AutoAnalyzer-II phosphate method. All of these methods 
          had been tested as implemented on the RFA-300 by comparison with an 
          AutoAnalyzer-II simultaneously running OSU's existing AutoAnalyzer-II methods. 
          The results were equal or better in all cases, with respect to accuracy, 
          precision, linearity and interferences.
          
          Sampling for nutrients followed that for the tracer gases, He, Tritium, CFCs, 
          and dissolved oxygen. Samples were drawn into 30cc high density polyethylene, 
          narrow mouth, screw-capped bottles. Then they were immediately introduced 
          into the RFA sampler by pouring into 4cc polystyrene cups which fit the RFA 
          sampler tray. Both the 30cc bottles and 4cc cups were rinsed three times with 
          rinses of approximately one third their volume prior to filling. Analyses 
          routinely were begun within twenty minutes after the 30cc bottles were filled 
          and completed within an additional hour and a half. When the RFA malfunctioned, 
          delays of up to several hours were experienced. If the delay was anticipated to 
          be more than one half hour, the samples were refrigerated. Samples were 
          refrigerated and stored up to 8 hours on stations 7-8. Station 13 was 
          refrigerated for ca. 6 hours. All samples from stations 1-6 were irretrievably 
          lost because of difficulties in starting up the RFA system at the beginning of 
          the expedition.
          
          During this cruise short-term precision was monitored by analyzing replicate 
          samples taken from the same Niskin bottle and by taking replicate samples from 
          Niskin bottles tripped at the same depth. Results from closely similar depths on 
          the same station were also compared. The results are shown in Table I. It is 
          emphasized that these data represent short-term precision, on order of minutes 
          to an hour.
          
          To check accuracy results were compared with historical data taken from the 
          region. Selected, modern, high quality data sets were used for the comparison. 
          The present data set compares within OSU's accuracy estimated from identified 
          sources of error and estimates of their magnitude, i.e., silicic acid, 2%; 
          phosphate, 1%; nitrate plus nitrite, 1%; and nitrite, 0.02 micromoles per liter. 
          The fractional values are relative to the highest concentrations found in the 
          regional water columns.
          
          
          TABLE I.  Short-term precision results for nutrient measurements from cruise 
                    OCEANUS 202. Entries are one standard deviation of a single analysis 
                    computed by pooling variances. Units are micromoles per liter 
                    throughout. Case I describes replicates taken from different Niskin 
                    bottles tripped at the same depth; case II, replicates from the same 
                    Niskin bottles; and case III, samples from closely adjacent depths. 
                    "DF" gives the number of degrees of freedom for each compiled set.
          
                   Case  Phosphate  Nitrate+Nitrite  Silicic Acid  Nitrite  DF
                   ----  ---------  ---------------  ------------  -------  --
                     I     0.012          0.10           0.16       0.01    63
                    II      .014           .10            .12        .005   93
                   III      .019           .16            .14        .01    30
          
          
          
          3.   CTD DATA COLLECTION, ANALYSES, AND PROCESSING
          
          CTD sensors and electronics have known response limitations in a dynamic 
          marine environment. To the extent that the instrument responses are stable and 
          repeatable, ODF and other groups can use an evolved set of sensor models, 
          calibration procedures, and algorithms to correct the output of the instrument. 
          ODF NBIS MkIII CTD data represents a successful application of these 
          procedures, with the possible exception of the oxygen sensor data. It is 
          possible under ideal circumstances to produce deep CTD data with an absolute 
          accuracy of about 2 dbar, 0.002C, and 0.002 psu. (Absolute accuracies are 
          sometimes worse, especially in high gradient and/or high ship roll situations.) 
          
          During ODF CTDO operations, pressure, temperature, conductivity, dissolved 
          oxygen, elapsed time, altimeter, transmissometer and voltage signals were 
          acquired from the underwater unit at a maximum frequency (i.e., for P, T, and C) 
          of 25 Hz. The data were transmitted as an FSK signal which was demodulated 
          by an ODF-designed deck unit. The deck unit output a 9600 baud RS-232C data 
          stream. An Integrated Solutions UNIX workstation computer served as the real 
          time data acquisition processor.
          
          Data acquisition consisted of storing all raw binary data and also generating 
          and storing a corrected and filtered 0.5-second average time series. (Audio data 
          were recorded on video tape as an ultimate back-up.) An absolute value and 
          first-order gradient single-frame filter was applied to each channel. For each 
          0.5 seconds of data, a 4,2 sigma standard deviation filter was passed over each 
          channel The remaining data for the 0.5 second block were then averaged. 
          Conductivity was corrected for thermal and pressure effects. Pressure and 
          conductivity were lagged to match the PRT temperature response. Pressure was 
          corrected for thermal and pressure hysteresis effects. Data calculated in real 
          time from this time series were reported and plotted during the cast. Also, an 
          average of the time series data (usually 10 seconds) was calculated for each 
          water sample collected during the data acquisition (these CTD values 
          corresponding to rosette bottle closures were also be recomputed later when 
          necessary). If required, a spike/drop-out filter was employed to remove 
          remaining large pressure, temperature and conductivity spikes from the 0.5-
          second time series data. (These were the type due to cable and slip ring noise, 
          for example.) A ship-roll filter (disallowing pressure reversals) was used 
          during the transformation of the data to a 2.0 dbar pressure series.
          
          
          3.1   CTD LABORATORY CALIBRATIONS
          
          The CTD pressure transducer was calibrated pre- and post-cruise in a 
          temperature-controlled bath to the ODF Ruska deadweight-tester pressure 
          standards. In the pressure calibration the mechanical hysteresis loading and 
          unloading curves were measured pre-/post-cruise at 0.2/0.5C to a maximum of 
          8830 psi, and at 28.5/28.1C to a maximum of 2030 psi. The transducer thermal 
          response time is derived from the pressure response to a thermal step change 
          from the high to the low bath temperatures. For high latitude work, the "high 
          temperature" calibration is often performed at 5C.
          
          The CTD PRT temperature transducer was calibrated pre- and post-cruise in a 
          temperature controlled bath with a NBLS ATB 1250 resistance bridge and a 
          Rosemount standard platinum resistance thermometer which is checked frequently 
          against the triple points of water and diphenyl ether. Seven or more calibration 
          temperatures between 0 and 31C were measured pre- and post-cruise. 
          
          
          3.2.   CTD PRESSURE CORRECTIONS
          
          The dynamic response of the pressure sensor is typically quite different than 
          the published specifications. Pressure error contributes inaccuracies to 
          properties (especially salinity) calculated from pressure and other 
          measurements. The pressure transducers used by ODF exhibit both a thermal 
          response and a pressure hysteresis. These response characteristics are 
          repeatable and can be corrected by a model based upon calibration experiments. 
          Since this type of sensor is prone to a pressure hysteresis that is dependent 
          upon the maximum loading pressure, the model utilizes a single loading pressure 
          calibration and multiple unloading pressure calibrations (to various maximum 
          pressures). The calibration is repeated at various calibration temperatures (see 
          above). A lagged temperature (calculated from the CTD PRT sensor temperature) is 
          used to model the internal transducer temperature, based upon thermal step 
          change response calibration data. In this way ODF can produce final CTD 
          pressures from the up and down casts accurate to 2 dbars. While this degree of 
          accuracy is not critical per se to most oceanographers, it minimizes the effects 
          of pressure errors on salinity calculations. 
          
          Thermometric pressures were not measured on this expedition. The pre- and post-
          cruise laboratory pressure calibrations were compared. Other than a small 
          offset, which was automatically adjusted for each cast as the CTD entered the 
          water, there was no remarkable difference between the two calibration results 
          for CTD #2. The pre- and post-cruise calibrations agreed within 2.5 decibars, 
          and there was no significant slope difference. No change was made to the 
          shipboard CTD pressure data, to which the pre-cruise pressure calibrations had 
          already been applied. Oceanus 202 pressures from stations with low ship roll are 
          probably accurate to about 3dbar, with some degradation probable at stations 
          with high ship roll. 
          
          
          3.3.   CTD TEMPERATURE CORRECTIONS
          
          CTD #2 had two PRTs. PRT #1 was the main temperature sensor and was used 
          exclusively in all data processing. PRT #2 was a secondary temperature sensor 
          installed to provide a check for the primary PRT. 
          
          A comparison of the pre- and post-cruise laboratory PRT temperature transducer 
          calibrations showed an average +0.0035C shift for PRT #1. and an average 
          +0.0030C shift for PRT #2. There was a also very small slope difference between 
          the two PRT #1 calibrations. There were no thermometric temperatures measured to 
          check for drifts or shifts in the CTD temperature sensor during the cruise, and 
          no remarkable instances of drift were observed. Bemuse there was far less 
          scatter in the pre-cruise results, the pre-cruise calibration coefficients were 
          used, plus an additional +0.002C offset to balance out the pre-/post-cruise 
          difference. 
          
          While the PRT laboratory calibration is thought to be accurate to within 
          0.001C Oceanus Cruise 202 temperatures in low gradient regions, i.e. where the 
          CTD electronics have stabilized to the ambient water temperature and the 
          response time errors are small, are probably accurate in absolute terms to about 
          0.002C. 
          
          
          3.4.   CTD CONDUCTIVITY CORRECTIONS
          
          Check-sample conductivities were calculated from the battle salinities using 
          corrected CTD pressures and temperatures. The differences between sample and CTD 
          conductivities from pressures less than 1500 decibars 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 
          slopes for each cast were fit to station number, giving a continuous smoothed 
          conductivity slope correction as a function of station number. Conductivity 
          differences were calculated for each cast after applying the preliminary 
          conductivity slope corrections. Residual conductivity offsets were then 
          calculated for each cast and fit to station number. The resulting smoothed 
          offsets were then applied to the data. 
          
          The conductivity sensor and/or electronics for CTD #2 displayed a sensitivity to 
          pressure change beginning about 1500 decibars. This effect was better isolated 
          by first applying the preliminary conductivity correction described above. After 
          careful examination, it was determined that the problem began about 1350 
          decibars, where the effect on conductivity was negligible. The distortion 
          continuously increased to the cast bottom, where the effect was approximately 
          0.03 mmhos/cm for a 6000-decibar cast. An additional first-order conductivity 
          slope as a function of pressure was determined using deep conductivity 
          differences:
          
                     newC = oldC - 6.34e-6*pressure + (Coffset at 1350 decibars)
          
          After applying this slope to the CTD data from 1350 decibars to the bottom of 
          each cast, the conductivity slope as a function of conductivity and conductivity 
          offset corrections were recalculated.
          
          All depth ranges were used to determine the final conductivity slopes as a 
          function of conductivity. The final smoothed slopes were determined in two 
          groups, with the first 69 stations grouped together and the rest of the 
          stations, with a constant slope, in the second group. Smoothed offsets were 
          applied to each cast, then manually adjusted to account for discontinuous shifts 
          in the conductivity transducer response, and/or to insure a consistent deep 
          theta-S relationship from station to station.
          
          The final bottle-CTD conductivity differences give the following results:
          
          
                                mean conductivity  standard   # values
                                 diff. (btl-CTD)   deviation  in mean
                                -----------------  ---------  --------
                 all pressures  -.00026 mmhos/cm    .00545      2956
                 allp (4,2rej)  -.00025 mmhos/cm    .00222      2775
                 press <= 1500  -.00009 mmhos/cm    .00685      1800
                 press >= 1500  -.00052 mmhos/cm    .00170      1156
          
                 ("4,2rej" means a 4,2 standard-deviation rejection filter  
                 was used on the differences before generating the results)
          
          
          3.5   CTD DISSOLVED OXYGEN DATA
          
          Dissolved oxygen data were acquired using a Sensormedics (Formerly Beckman) 
          dissolved oxygen sensor. The same oxygen sensor was used during the entire 
          cruise. Sufficient (>12/cast) high-quality oxygen check samples were collected 
          to make CTD oxygen calibration feasible.
          
          CTD down-cast raw oxygen currents were extracted from the corrected pressure-
          series data at isopycnals corresponding to the up-cast check-samples. The 
          differences between CTD and check-sample dissolved oxygens were used to generate 
          coefficients for a sensor model on a station-by-station basis. In the ODF 
          software model of the response of the Beckman dissolved O2 sensor, filters are 
          employed to correct for temperature and pressure response. The temperature at 
          the surface of the sensor membrane is calculated and used to compute the 
          diffusion time constant for the membrane. A diffusion time delay is also 
          calculated. Pressure, temperature and salinity are found at the diffusion time 
          and modeled to match the O2 response. Oxygen partial pressure is then calculated 
          taking into account the dissolved O2 partial-pressure in atmospheres, the sensor 
          current, the offset current of the sensor, the pressure at response-time, the 
          pressure correction coefficient, the temperature correction coefficient, the 
          temperature at response-time, the salinity at response-time, the salinity 
          correction coefficient, the natural log of the slope of O2 conversion, and the 
          offset of O2 conversion. Modeling coefficients are determined by applying a non-
          linear fitting procedure to residual differences derived from Winkler titration 
          check sample data.
          
          The statistics below represent the final bottle-CTD oxygen differences: 
          
          
                                 mean oxygen       standard   # values
                                diff.(btl-CTD)     deviation  in mean
                                --------------     ---------  --------
                 all pressures  +.0009 ml/l         .0921       3037
                 allp (4,2rej)  +.0030 ml/l         .0371       2827
                 press <=1500   -.0001 ml/l         .1137       1874
                 press >=1500   +.0025 ml/l         .0366       1163
          
                 ("4,2rej" means a 4,2 standard-deviation rejection filter 
                 was used on the differences before generating the results)
          
          
          Several casts in this cruise did not have any bottle data for an extensive 
          portion of the cast. Bottle oxygen values from nearby stations were matched up 
          to those down-casts in order to ensure a reasonable data fit. The following 
          casts were affected: station 61-63 cast 1 (used corresponding cast 2 oxygens for 
          missing bottles above 1200 decibars), station 64 cast 1 (used station 63 cast 1 
          bottle values between 3800 decibars and bottom), and station 127 cast 1 (used 
          station 126 cast 1 bottles, where reasonable, above 3800 decibars). These added 
          bottle differences were included when generating the final statistics in the 
          paragraph above.
          
          The oxygen sensor often requires several seconds in the water before it is wet 
          enough to respond properly; this is manifested as low 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 down-cast oxygen data 
          are typically better because of the more continuous lowering rate; any non-
          bottom CTD stops observed in the down-trace data are documented in the CTD 
          Processing Notes (Appendix A).
          
          Several casts without bottom oxygen bottle values did not have an appropriate 
          nearby-cast bottle to substitute. The bottom data of the CTD traces for such 
          casts tend to wander a little in the low direction. This may happen on other 
          casts because of slowing down the package for the bottom approach.
          
          
          3.6.   ADDITIONAL PROCESSING 
          
          A software filter was used on half of the casts to remove various conductivity, 
          temperature, or oxygen spiking problems. These spiking problems were due to 
          signal reception problems caused by slip rings, pylon noise (numerous new end 
          terminations and signal problems on this expedition) and ship-roll generated 
          spiking not solved by the roll filter. Overall, less than 0.4% of the time-
          series data in those casts were affected. Pressure did not require filtering. 
          The down-cast (up-cast for Stations 10, 115, and 125) portion of each time-
          series was then pressure-sequenced into 2-decibar pressure intervals. A ship-
          roll filter was applied to disallow pressure reversals on every cast except 
          station 11 cast 2: a 17 percent reduction in the number of missing data levels 
          for this cast resulted from not using the filter.
          
          Density inversions which still remain 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 miring 
          occurring in these areas as a consequence of ship roll. The ship-roll filter 
          resulted in a reduction in the amount and/or size of density inversions.
          
          Several shipboard time-series data sets had problems with large areas of missing 
          or noisy data. Many of these casts were partially or fully recovered by re-
          digitizing the raw signal from analog tape. Those casts which could not be fully 
          recovered by filtering or re-digitizing are documented in the CTD Processing 
          Notes (Appendix A). All other remaining problems are documented in the inventory 
          as well.
          
          
          3.7.   GENERAL COMMENTS/PROBLEMS 
          
          There is one pressure-sequenced CTD- data set, to near the ocean floor, for each 
          of 129 stations, numbered 1 through 129. There were also 4 stations - 61, 62, 
          63, and 65 - which had two casts (deep and shallow) in order to recover 
          shallower bottle data information missed on the deep casts because of rosette 
          malfunctions, there were two shakedown stations, and there was one aborted cast, 
          for a total of 136 CTD casts. The first three of the two cast stations were 
          collected during re-occupations of the stations (about 22 hours later). These 
          four shallower casts were originally given a cast number of 11 but are now 
          called cast 2. The aborted cast was carried out at Station 11, and another CTD 
          cast was done immediately afterward at the same location (and called cast 2). 
          The data from the shakedown stations are not included in any distributions of 
          the data.
          
          The data reported are all from down-casts with the exception of stations 10, 115 
          and 125 (all cast 1), which are up-casts. The up-cast was used for Station 10 
          cast 1 because the down-cast had significantly more noise/gaps than the up-cast. 
          Station 115 cast 1 down-cast had one large 280-decibar data gap, and the up-cast 
          was fine. Station 125 cast 1 down-cast had several large data gaps (40-300+ 
          decibars) which were not recoverable from analog tape, the up-cast was recovered 
          with no gaps and without the signal-noise problems experienced shipboard.
          
          Other casts with notable problems are as follows: Station 10 cast 1 up-cast, 
          although better than the down-cast, has 1% missing data; its largest 
          interpolated gap is 5 consecutive levels. Station 35 cast 1 down-cast was 
          recorded from 14 decibars in-the-water; the up-cast showed this area to be 
          within a good mixed layer. The down-cast, with the surface levels extrapolated, 
          was used because of the benefit of using down-casts for oxygen processing. 
          Station 11 cast 2 had many gaps: 5% of its data, including one 50-decibar gap, 
          were missing and interpolated. Its down-cast was used because the up-cast was 
          just as bad. Station 112 cast 1 also had gapping problems: 4%of its data were 
          missing and interpolated, much of it concentrated in one 110-decibar gap. In 
          general, missing data levels have been extrapolated/interpolated. All pertinent 
          comments/problems from shipboard and post-processing notes are documented in the 
          CTD Processing Notes (Appendix A).
          
          Most gaps in Oceanus 202 CTD data were caused by signal interruption between the 
          CTD and shipboard equipment, i.e. from slip ring and/or end termination 
          problems. When possible, missing data were recovered from the raw data 
          (videotape) backup, i.e. when the problems were caused by deck unit 
          maladjustment. Low recording volume on the video backup prevented data recovery 
          for the Station 125 down cast.
          
          The 0-decibar level of some casts was extrapolated using a quadratic fit through 
          the next three deeper levels. Recorded surface values have been rejected only 
          when it is fairly obvious that the drift is due to the sensors adjusting to the 
          in-water transition; if there is any doubt or a possibility that the data is 
          real, it is left alone. Extrapolated surface levels, as well as other single 
          interpolated levels which fill in for missing data, are documented in the CTD 
          Processing Notes. The interpolated levels for the three stations with multiple 
          problems, mentioned above, are documented in the CTD Processing Notes (Appendix 
          A).
          
          During post-cruise conductivity data calibrations it was noticed that there was 
          an apparent +0.002 conductivity offset in the deep data for some stations. This 
          apparent offset appeared in both the down-casts and up-casts 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, that is, when 
          the most significant bit in the 16 bit number is turned off. On some stations, a 
          -0.002 shift back appears yet deeper, where the raw conductivity value crosses 
          back over to 32.767 from the other direction. This problem indicates need for 
          instrument service. It is most noticeable in Atlantic Ocean data because this 
          particular conductivity "crossover" value typically occurs in deep water, where 
          salinity is fairly stable over many hundreds of meters.
          
          There were various winch, wire and rosette problems throughout the cruise. This 
          resulted in numerous stops, pauses or yoyos during casts. Only the most 
          significant of these have been noted. As mentioned above, these severe changes 
          in the lowering rate can affect oxygen data in particular.
          
          
          
          4.   DATA TABLES AND PLOTS 
          
          4.1.   STATION AND CAST DESCRIPTION 
          
          Latitudes and longitudes were read from the ship's navigation system. The "Start 
          Up" time is the time (GMT) at the beginning of the CTD up cast. 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. If one adds the reported distance above bottom to the maximum sampling 
          depth (reported in the CTD data) to calculate the ocean depth, there is often a 
          difference, due to the difference in method of measurement of maximum sampling 
          depth versus ocean depth. Also note that the maximum sampling depth 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 24 bottles were 
          sampled, the number of samples taken are reported in the comments. The 
          complementary programs are reported in the "Samples" column.
          
          
          4.2.  TABULAR DATA, CTD AND NISKIN BOTTLE
          
          Station numbers are consecutive from the beginning to end of the crime, without 
          interruption, except for two unreported test stations. Cast numbers are 
          consecutive at each station, including aborted casts. However, at stations 61, 
          62, and 63, the second cast took place during reoccupations about 18 hours to 4 
          days later. Meteorological data were collected by the shies officers and were 
          copied from the Oceanus Bridge Log.
          
          The headings in both the CTD data and NISKIN bottle data have been abbreviated 
          to PRESS, TEMP, and O2 for pressure (decibars), temperature (degrees Celsius), 
          and oxygen (milliliters per liter). 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), Dynamic Height (dynamic 
          meters) to DYN HT, (Sverdrup et al, 1942), Sound Velocity (meter per second) to 
          SVEL, (Chen and Millero, 1977), Vaisala Frequency (cycles per hour) to VAIS FREQ 
          which uses a subroutine by Bob Millard modified by Lynne Talley to incorporate 
          Gaussian weighting after formulation of Breck Owens and N. P. Fofonoff. In the 
          bottle data listings, the headings have been abbreviated to O2 SAT, (Weiss, 
          1970), SIO3, PO4, NO3, and NO2 for oxygen saturation (percent saturation), 
          silicate, phosphate, nitrate, and nitrite (micromoles/liter), 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=0, from 
          which 1000 has been subtracted. Potential temperature, theta, (degrees celsius) 
          has been calculated according to Fofonoff (1977) and Bryden (1973) and depth 
          (meters) by Saunders (1981) and Mantyla (1982-1983).
          
          Throughout the battle data report alphabetic characters may be found in the 
          tabular data. These characters have the following meaning.
          
            D   A salinity value, tormally (default) from a bottle sample, 
                has been taken from CTD records.
          
            U   A data value is suspect, although no obvious reason has been found.
          
          Comments and investigation of these values are reported in APPENDIX B
          
          
          4.3.  STATION PLOTS
          
          The hydrographic station plots provide a visualization of the data that is not 
          possible from listings. For each station, the upper plots are CTD data, the 
          lower two plots are bottle data.
          
          
          4.4.  VERTICAL SECTIONS
          
          The vertical sections were contributed by Mizuki Tsuchiya and Lynne Talley and 
          are being published by Tsuchiya, Talley and McCartney (1991). The potential 
          temperature, salinity and potential density sections are based on CTD data. Note 
          for the potential density section that sigma-theta is contoured on the 0-1500 
          meter panel, while sigma2 is contoured from 0-3000 meters and sigma4 is 
          contoured from 3000-6000 meters on the full-depth panel. The oxygen, silica, 
          nitrate and phosphate sections are band on discrete data; the CTD profiles were 
          used to resolve some difficulties in contouring oxygen.
          
          
          
          5.   ACKNOWLEDGEMENTS 
          
          This data set was acquired under National Science Foundation Grant OCE 86-14486. 
          The assistance provided by Dr. Thomas W. Spence is gratefully acknowledged.
          
          
          
          6.   REFERENCES 
          
          Alpkem Corporation, 1987. Operator's Manual RFA-300, Preliminary Version. 
              Clackamus, Oregon. Unnumbered, loose leaf pages.
          Atlas, E.L., S.W. Hager, L.I. Gordon and P.K. Park, 1971. A Practical Manual for 
              Use of the Technicon AutoAnalyzer in Seawater Nutrient Analyses; Revised. 
              Technical Report 215, Reference 71-22. Oregon State University, Department of 
              Oceanography. 49 pp.
          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 Defence, Taunton Somerset.
          Chen, C.-T. and F.J. Millero, 1977. Speed of sound in seawater at high 
              pressures. Journal Acoustical Society of America, Volume 62, No. 5, 1129-1135.
          Fofonoff, N.P. 1977. Computation of Potential Temperature of Seawater for an 
              Arbitrary Reference Pressure. Deep-Sea Research 24, 489-491.
          Fofonoff, N.P. and R.C. Millard, 1983. Algorithms for Computation of Fundamental 
              Properties of Seawater. UNESCO Report No. 44, 15-24.
          Lewis, E.L., 1980. The Practical Salinity Scale 1978 and Its Antecedents. IEEE 
              Journal of Oceanographic Engineering, OE-5, 3-8.
          Mantyla, A. W. 1982-1983. Private correspondence.
          Millero, F.J., C.-T. Chen, A. Bradshaw and K. Schleicher, 1980. A New High 
              Pressure Equation of State for Seawater. Deep-Sea Research 27A, 255-264.
          Saunders, P.M. 1981. Practical Conversion of Pressure to Depth. Journal of 
              Physical Oceanography 11, 573-574.
          Sverdrup, H.U., M.W. Johnson, and R.H. Fleming, 1942. The Oceans, Their Physics, 
              Chemistry and General Biology. Prentice-Hall, Inc., Englewood Cliff, N.J.
          Tsuchiya, M., L.D. Talley and M.S. McCartney, 1991. An eastern Atlantic section 
              from Iceland southward across the equator. Submitted to Deep-Sea Research.
          UNESCO, 1981. Background papers and supporting data on the Practical Salinity 
              Scale, 1978. UNESCO Technical Papers in Marine Science, No. 37, 144 p.
          Weiss, R.F., 1970. The solubility of nitrogen, oxygen and argon in water and 
              seawater. Deep-Sea Research 17, 721-735.
          
          
          
          ___________________________________________________________________________________________________________
          ___________________________________________________________________________________________________________
          
          
          
          
          7.  CHLOROFLUOROCARBON ANALYSIS METHODS
              (John Bullister) 
          
          Specially designed 2 liter water sample bottles were used on the cruise
          to reduce CFC contamination.  These bottles have a modified end-cap
          design to minimize the contact of the water sample with the end-cap
          O-rings after closing.  The O-rings used in these water sample bottles
          were vacuum-baked prior to the first station. Stainless steel springs
          covered with an epoxy powder coat were used inside the bottles (instead
          of elastic tubing) used close the bottles.
          
          Water samples for CFC analysis were usually the first samples collected
          from the 2 liter bottles.  Care was taken to co-ordinate the sampling
          of CFCs with other samples to minimize the time between the initial
          opening of each bottle and the completion of sample drawing.  In most
          cases, dissolved oxygen, helium/tritium and nutrient samples were
          collected within several minutes of the initial opening of each
          bottle.  To minimize contact with air, the CFC samples were drawn
          directly through the stopcocks of the 2 liter bottles into 100 ml
          precision glass syringes equipped with 2-way metal stopcocks.  The
          syringes were immersed in a holding tank of clean surface seawater
          until analyses.
          
          For air sampling, a ~100 meter length of 3/8" OD Dekaron tubing was run
          from the analytical system to the bow of the ship.  Air was sucked
          through this line using an Air Cadet pump.  The air was compressed in
          the pump, with the downstream pressure held at about 1.5 atm using a
          back-pressure regulator.  A tee allowed a flow (~100 cc/min) of the
          compressed air to be directed to the gas sample valves, while the bulk
          flow of the air (>7 liter/minute) was vented through the back pressure
          regulator.
          
          Concentrations of CFC-11 and CFC-12 in air samples, seawater and gas
          standards on the cruise were measured by shipboard electron capture gas
          chromatography (EC-GC), using the techniques described by Bullister and
          Weiss (1988).  For seawater analyses, a ~30-ml aliquot of seawater from
          the glass syringe was transferred into the glass sparging chamber.  The
          dissolved CFCs in the seawater sample were extracted by passing a
          supply of CFC-free purge gas through the sparging chamber for a period
          of 4 minutes at ~70 cc/min.  Water vapor was removed from the purge gas
          while passing through a short tube of magnesium perchlorate desiccant.
          The sample gases were concentrated on a cold-trap consisting of a
          2-inch section of 1/8-inch stainless steel tubing packed with Porasil C
          (80-100 mesh) backed by a 2 inch section packed with Porapak T (80-100
          mesh) immersed in a bath of isopropanol held at -20 degrees C.  After 4
          minutes of purging the seawater sample, the sparging chamber was closed
          and the trap isolated.  The dewer full of cold isopropanol was removed
          and the trap was submerged into a dewar of boiling water.  The sample
          gases held in the trap were then injected onto a precolumn (12 inches
          of 1/8-inch O.D. stainless steel tubing packed with 80-100 mesh
          Porasil C, held at 90 degrees C), for the initial separation of the
          CFCs and other rapidly eluting gases from more slowly eluting
          compounds.  The CFCs then passed into the main analytical column (10
          feet, 1/8-inch stainless steel tubing packed with Porasil C 80-100
          mesh, held at 90 degrees C), and then into the EC detector.
          
          The CFC analytical system was calibrated frequently using standard gas
          of known CFC composition.  Gas sample loops of known volume were
          thoroughly flushed with standard gas and injected into the system.  The
          temperature and pressure were recorded so that the amount of gas
          injected could be calculated.  The procedures used to transfer the
          standard gas to the trap, precolumn, main chromatographic column and EC
          detector were similar to those used for analyzing water samples.  Two
          sizes of gas sample loops were present in the analytical system.
          Multiple injections of these loop volumes could be done to allow the
          system to be calibrated over a relatively wide range of CFC
          concentrations.  Air samples and system blanks (injections of loops of
          CFC-free gas) were injected and analyzed in a similar manner.  The
          typical analysis time for seawater, air, standard and blank samples was
          about 8 minutes.
          
          Concentrations of CFC-11 and CFC-12 in air, seawater samples and gas
          standards are reported relative to the SIO93 calibration scale
          (Cunnold, et. al., 1994).  CFC concentrations in air and standard gas
          are reported in units of mole fraction CFC in dry gas, and are
          typically in the parts-per-trillion (ppt) range.  Dissolved CFC
          concentrations are given in units of picomoles of CFC per kg seawater
          (pmol/kg).  CFC concentrations in air and seawater samples were
          determined by fitting their chromatographic peak areas to multi-point
          calibration curves, generated by injecting multiple sample loops of gas
          from a CFC working standard (cylinder 9944) into the analytical
          instrument.  The concentrations of CFC-11 and CFC-12 in this working
          standard were calibrated before and after the cruise versus a primary
          standard (36743) (Bullister, 1984).  No measurable drift in the
          concentrations of CFC-11 and CFC-12 in the working standard could be
          detected during this interval.  Full range calibration curves were run
          at intervals of ~ 3 days during the cruise.  Single injections of a
          fixed volume of standard gas at one atmosphere were run much more
          frequently (at intervals of 1 to 2 hours) to monitor short term changes
          in detector sensitivity.
          
          The small volume (~2 liter) water sampling bottles were designed and
          constructed prior to this cruise because of the small rosette package
          used.  The inner surfaces of the bottles may not have had adequate time
          to desorb any excess levels of CFCs present in the PVC pipe used to
          construct the bottles, and this may have contributed to the relatively
          high and variable CFC-11 blanks observed in some samples.
          CFC blanks were estimated from samples collected in regions where low
          or CFC-free water was expected.  Measured CFC-12 concentrations were
          consistently low and near the detection limit for depths between
          2000-4000 meters from 30N -14N, and these samples were used to
          estimate the mean CFC blanks for the expedition.  A CFC-12 blank
          correction of 0.001 pmol/kg was applied to the entire cruise.  The
          CFC-11 blanks were higher and more variable with an average of ~0.06
          pmol/kg (see listing of replicate samples given at the end of this
          report).  In some cases, applying these blank corrections to low
          concentration samples yields negative reported concentrations.
          
          On this expedition, we estimate precisions (1 standard deviation) to be
          the greater of about 0.018 pmol/kg or 1.8% for dissolved CFC-11 and
          0.004 pmol/kg or 1.5% for CFC-12.
          
          A number of water samples had clearly anomolous CFC-11 and/or CFC-12
          concentrations relative to adjacent samples.  These anomolous samples
          appeared to occur more or less randomly during the cruise, and were not
          clearly associated with other features in the water column (eg.
          elevated oxygen concentrations, salinity or temperature features,
          etc.).  This suggests that the high values were due to individual,
          isolated low-level CFC contamination events. These samples are included 
          in this report and are give a quality flag of either 3 (questionable 
          measurement) or 4 (bad measurement).  A total of ~116 analyses of CFC-11 
          were assigned a flag of 3 and ~46 analyses of CFC-12 were assigned a flag 
          of 3. A total of ~112 analyses of CFC-11 were assigned a flag of 4 and ~89 
          CFC-12 samples assigned a flag of 4.
          
          In addition to the file of mean CFC concentrations reported for each
          water sample in the data tables (keyed to the unique station: sample
          ID), tables of the following are included in this report:
          
          
          TABLE 1a. A16N Replicate dissolved CFC-11 analyses
          TABLE 1b. A16N Replicate dissolved CFC-12 analyses
          TABLE 2.  A16N CFC air measurements 
          TABLE 3.  A16N CFC air measurements (interpolated to station locations)
          
          
          A value of -9.0 is used for missing values in the listings.
          
          
          
          REFERENCES:
          
          Bullister, J.L.  Anthropogenic Chlorofluoromethanes as Tracers of
              Ocean Circulation and Mixing Processes:  Measurement and Calibration
              Techniques and Studies in the Greenland and Norwegian Seas, Ph.D.
              dissertation, Univ. Calif. San Diego, 172 pp.
          Bullister, J.L. and R.F. Weiss,  Determination of CCl3F and CCl2F2 in
              seawater and air. Deep-Sea Research, 35 (5), 839-853, 1988.
          Cunnold, D.M., P.J. Fraser, R.F. Weiss, R.G. Prinn, P.G. Simmonds,
              B.R. Miller,F.N. Alyea,  and A.J.Crawford. Global trends and annual
              releases of CCl3F and CCl2F2 estimated from ALE/GAGE and other
              measurements from July 1978 to June 1991.  J.  Geophys. Res., 99,
              1107-1126, 1994.
          
          
          
          TABLE 1A. A16N REPLICATE DISSOLVED CFC-11 ANALYSES
          
          STN  SAMP  F-11  | STN  SAMP  F-11  | STN  SAMP  F-11  | STN  SAMP  F-11  
          ---  ----  ----- | ---  ----  ----- | ---  ----  ----- | ---  ----  -----
           13   24   1.699 |  43   24   0.055 |  61   23   0.030 |  65  23    0.097
           13   24   1.705 |  43   24   0.096 |  62   15   0.189 |  65  24    0.046
           14   14   1.709 |  47   22   0.191 |  62   15   0.209 |  65  24    0.077
           14   14   1.692 |  47   22   0.168 |  62   17   0.091 |  65  24    0.027
           20    6   3.321 |  47   23   0.173 |  62   17   0.108 |  69  20    0.026
           20    6   3.292 |  47   23   0.171 |  62   18   0.090 |  69  20    0.001
           20   22   1.463 |  47   23   0.166 |  62   18   0.019 |  69  21    0.007
           20   22   1.477 |  49    4   2.654 |  62   18   0.032 |  69  21   -0.002
           35   22   0.102 |  49    4   2.771 |  62   18   0.063 |  69  22    0.011
           35   22   0.097 |  50    6   2.694 |  62   19   0.027 |  69  22   -0.032
           35   23   0.058 |  50    6   2.625 |  62   19   0.010 |  69  23    0.010
           35   23   0.039 |  50   24   0.047 |  62   19   0.013 |  69  23   -0.022
           36   22   0.075 |  50   24   0.040 |  62   20   0.043 |  69  24   -0.006
           36   22   0.082 |  50   24   0.033 |  62   20   0.028 |  69  24   -0.030
           36   24   0.023 |  51   22   0.028 |  62   20   0.029 |  72   1    2.036
           36   24   0.019 |  51   22   0.040 |  62   21   0.007 |  72   1    1.984
           37   23   0.117 |  55   21   0.033 |  62   21   0.015 |  72   2    2.080
           37   23   0.067 |  55   21   0.029 |  62   21   0.000 |  72   2    1.995
           37   24   0.060 |  55   23   0.045 |  62   23   0.032 |  72   3    2.170
           37   24   0.060 |  55   23   0.061 |  62   23   0.015 |  72   3    2.228
           41   20   0.162 |  55   24   0.059 |  65    1   0.099 |  72   4    2.124
           41   20   0.161 |  55   24   0.038 |  65    1   0.070 |  72   4    2.264
           42   20   0.276 |  59    2   2.445 |  65    1   0.058 |  72   5    2.252
           42   20   0.197 |  59    2   2.409 |  65   20   0.039 |  72   5    2.263
           42   21   0.264 |  61   20   0.023 |  65   20   0.007 | 124  19    0.011
           42   21   0.278 |  61   20   0.062 |  65   21   0.017 | 124  19    0.018
           42   22   0.094 |  61   20   0.001 |  65   21   0.071 | 124  24   -0.013
           42   22   0.138 |  61   21   0.000 |  65   21   0.003 | 124  24    0.010
           43   22   0.119 |  61   21   0.011 |  65   22   0.017 | 125  21    0.023
           43   22   0.098 |  61   21   0.002 |  65   22   0.013 | 125  21    0.017
           43   22   0.084 |  61   22   0.035 |  65   22   0.038 | 127  14   -0.018
           43   23   0.058 |  61   22   0.020 |  65   23   0.040 | 127  14   -0.018
           43   23   0.055 |  61   23   0.040 |  65   23   0.043 | 
          
          
          
          
          TABLE 1b. A16N Replicate dissolved CFC-12 analyses
          
          STN  SAMP  F-12  | STN  SAMP  F-12  | STN  SAMP  F-12  | STN  SAMP  F-12 
          ---  ----  ----- | ---  ----  ----- | ---  ----  ----- | ---  ----  -----
           13   24   0.724 |  43   23   0.011 |  61   21   0.007 |  65  23   -0.001
           13   24   0.719 |  47   22   0.103 |  61   21   0.007 |  65  23    0.007
           14   14   0.747 |  47   22   0.088 |  61   22   0.011 |  65  23    0.006
           14   14   0.816 |  47   23   0.080 |  61   22   0.003 |  65  24    0.010
           20    6   1.540 |  47   23   0.079 |  61   22   0.003 |  65  24    0.010
           20    6   1.551 |  47   23   0.093 |  61   23  -0.001 |  65  24    0.017
           20   22   0.681 |  49    4   1.277 |  61   23   0.003 |  69  20   -0.001
           20   22   0.801 |  49    4   1.320 |  61   23   0.007 |  69  20    0.002
           35   22   0.023 |  50    6   1.241 |  62   15   0.072 |  69  21    0.002
           35   22   0.026 |  50    6   1.246 |  62   15   0.101 |  69  21    0.002
           35   23   0.031 |  50   24   0.023 |  62   17   0.026 |  69  22    0.002
           35   23   0.036 |  50   24   0.043 |  62   17   0.023 |  69  22    0.002
           36   22   0.011 |  50   24   0.020 |  62   18   0.037 |  69  23   -0.001
           36   22   0.021 |  51   22   0.003 |  62   18   0.028 |  69  23   -0.001
           36   23   0.024 |  51   22   0.007 |  62   18   0.023 |  69  24    0.002
           36   23   0.011 |  51   23  -0.001 |  62   18   0.033 |  69  24   -0.001
           36   24   0.043 |  51   23   0.003 |  62   19   0.003 |  72   1    0.974
           36   24   0.007 |  53   23   0.003 |  62   19   0.007 |  72   1    0.959
           36   24   0.014 |  53   23   0.003 |  62   19   0.003 |  72   2    0.947
           36   24   0.025 |  55   20   0.022 |  62   20   0.007 |  72   2    0.963
           37   22   0.027 |  55   20   0.017 |  62   20   0.010 |  72   3    1.039
           37   22   0.018 |  55   21   0.027 |  62   20   0.007 |  72   3    1.065
           37   23   0.022 |  55   21   0.027 |  62   21   0.003 |  72   4    1.009
           37   23   0.011 |  55   21   0.026 |  62   21   0.006 |  72   4    1.087
           37   24   0.025 |  55   22   0.035 |  62   21   0.007 |  72   5    1.072
           37   24   0.020 |  55   22   0.027 |  62   22   0.006 |  72   5    1.072
           37   24   0.019 |  55   22   0.040 |  62   22   0.014 | 124  19    0.008
           38   23   0.052 |  55   23   0.024 |  62   23   0.007 | 124  19    0.012
           38   23   0.046 |  55   23   0.035 |  62   23   0.003 | 124  20    0.005
           41   20   0.059 |  55   23   0.023 |  62   24   0.011 | 124  20    0.002
           41   20   0.071 |  55   24   0.007 |  62   24   0.003 | 124  21    0.005
           41   22   0.033 |  55   24   0.014 |  65    1   0.017 | 124  21    0.002
           41   22   0.049 |  55   24   0.021 |  65    1   0.006 | 124  22   -0.001
           42   20   0.122 |  59    2   1.145 |  65    1  -0.001 | 124  22    0.005
           42   20   0.142 |  59    2   1.129 |  65   20   0.003 | 124  24    0.002
           42   21   0.090 |  59   21   0.014 |  65   20   0.007 | 124  24    0.005
           42   21   0.110 |  59   21   0.020 |  65   20   0.016 | 125  21    0.011
           42   22   0.057 |  59   24   0.011 |  65   21   0.006 | 125  21    0.008
           42   22   0.047 |  59   24   0.003 |  65   21  -0.001 | 127  14    0.017
           43   22   0.032 |  61   20  -0.001 |  65   21   0.006 | 127  14    0.017
           43   22   0.035 |  61   20   0.003 |  65   22   0.003 | 
           43   22   0.028 |  61   20   0.007 |  65   22   0.003 |
           43   23   0.025 |  61   21  -0.001 |  65   22   0.007 |
          
           
          
          TABLE 2.    A16N CFC AIR MEASUREMENTS: 
          
          LEG 1
                       TIME                               F11      F12  
          DATE        (hhmm)   LATITUDE     LONGITUDE     PPT      PPT
          ---------   ------   ---------    ----------    -----    -----
          27 Jul 88    2240    53 58.9 N    020 00.0 W    257.6    459.6
          27 Jul 88    2250    53 58.9 N    020 00.0 W    254.9    457.9
          27 Jul 88    2302    53 58.9 N    020 00.0 W    254.7    457.5
          28 Jul 88    2138    51 29.0 N    020 00.0 W    252.8    456.0
          28 Jul 88    2147    51 29.0 N    020 00.0 W    252.5    458.4
          28 Jul 88    2157    51 29.0 N    020 00.0 W    252.8    457.9
          31 Jul 88    1539    44 59.8 N    019 19.0 W    255.8    457.4
          31 Jul 88    1549    44 59.8 N    019 19.0 W    253.9    459.3
          31 Jul 88    1557    44 59.8 N    019 19.0 W    252.8    458.3
           1 Aug 88    1730    42 30.2 N    020 00.4 W    252.3    457.6
           1 Aug 88    1740    42 30.2 N    020 00.4 W    251.4    457.1
           1 Aug 88    1750    42 30.2 N    020 00.4 W    252.2    456.1
           3 Aug 88    0542    38 59.0 N    020 00.0 W    251.9    458.1
           3 Aug 88    0553    38 59.0 N    020 00.0 W    251.8    459.4
           3 Aug 88    1606    38 00.7 N    019 59.3 W    250.3    460.0
           3 Aug 88    1616    38 00.7 N    019 59.3 W    250.8    459.8
           3 Aug 88    1627    38 00.7 N    019 59.3 W    250.9    459.9
           4 Aug 88    1102    36 00.2 N    020 00.7 W    253.3    458.9
           4 Aug 88    1115    36 00.2 N    020 00.7 W    252.8    461.3
           4 Aug 88    1125    36 00.2 N    020 00.7 W    251.9    459.2
           5 Aug 88    0524    34 40.5 N    020 48.7 W    251.1    453.9
           5 Aug 88    0535    34 40.5 N    020 48.7 W    250.5    456.6
          
          
          LEG 2
                       TIME                               F11      F12  
          DATE        (hhmm)   LATITUDE     LONGITUDE     PPT      PPT
          ---------   ------   ---------    ----------    -----    -----
          12 Aug 88    0551    31 03.0 N    022 55.0 W    247.4    460.5
          12 Aug 88    0602    31 03.0 N    022 55.0 W    247.1    459.3
          12 Aug 88    0614    31 03.0 N    022 55.0 W    244.8    462.5
          13 Aug 88    2104    26 44.9 N    025 16.5 W    250.8    459.9
          14 Aug 88    2030    24 00.2 N    026 54.7 W    251.9    461.7
          15 Aug 88    1253    22 43.6 N    027 28.6 W    248.4    453.4
          19 Aug 88    1058    10 18.0 N    028 41.3 W    234.9    442.1
          19 Aug 88    1111    10 18.0 N    028 41.3 W    235.4    440.0
          19 Aug 88    1126    10 18.0 N    028 41.3 W    238.9    445.4
          20 Aug 88    2225    06 48.0 N    027 12.0 W    233.9    437.3
          20 Aug 88    2235    06 48.0 N    027 12.0 W    234.0    433.9
          21 Aug 88    2134    04 06.0 N    026 06.0 W    231.6    436.0
          21 Aug 88    2145    04 06.0 N    026 06.0 W    232.8    437.5
          21 Aug 88    2155    04 06.0 N    026 06.0 W    232.9    434.1
          22 Aug 88    0428    02 41.4 N    025 29.6 W    232.3    435.2
          22 Aug 88    0438    02 41.4 N    025 29.6 W    231.4    441.5
          22 Aug 88    0448    02 41.4 N    025 29.6 W    238.4    441.0
          22 Aug 88    0459    02 41.4 N    025 29.6 W    233.1    437.2
          24 Aug 88    1212    01 30.0 S    025 00.0 W    235.3    437.2
          24 Aug 88    1222    01 30.0 S    025 00.0 W    234.8    431.8
          24 Aug 88    1232    01 30.0 S    025 00.0 W    231.3    429.5
           
          
          
          TABLE 3. A16N CFC AIR VALUES (INTERPOLATED TO STATION LOCATIONS)
           
                                                         F11      F12
          STN    LATITUDE     LONGITUDE     DATE         PPT      PPT
          ---    ---------    ----------    ---------    -----    -----
            1    63 19.8 N    019 59.9 W    23 Jul 88    254.2    457.9
            2    63 12.6 N    020 00.3 W    23 Jul 88    254.2    457.9
            3    63 08.0 N    020 00.4 W    24 Jul 88    254.2    457.9
            4    62 59.3 N    020 00.7 W    24 Jul 88    254.2    457.9
            5    62 40.3 N    019 59.9 W    24 Jul 88    254.2    457.9
            6    62 19.8 N    020 00.1 W    24 Jul 88    254.2    457.9
            7    61 49.6 N    020 01.3 W    24 Jul 88    254.2    457.9
            8    61 19.6 N    020 00.8 W    24 Jul 88    254.2    457.9
            9    60 49.5 N    019 58.9 W    24 Jul 88    254.2    457.9
           10    60 19.6 N    019 59.9 W    25 Jul 88    254.2    457.9
           11    59 50.6 N    019 59.2 W    25 Jul 88    254.2    457.9
           12    59 23.6 N    019 59.2 W    25 Jul 88    254.2    457.9
           13    58 49.4 N    020 00.8 W    26 Jul 88    254.2    457.9
           14    58 22.5 N    020 01.2 W    26 Jul 88    254.2    457.9
           15    57 59.6 N    020 00.8 W    26 Jul 88    254.2    457.9
           16    57 29.5 N    020 00.6 W    26 Jul 88    254.2    457.9
           17    56 59.2 N    020 01.2 W    26 Jul 88    254.2    457.9
           18    56 29.2 N    020 01.2 W    27 Jul 88    254.2    457.9
           19    55 59.3 N    020 01.8 W    27 Jul 88    254.2    457.9
           20    55 29.3 N    020 00.6 W    27 Jul 88    254.2    457.9
           21    54 59.1 N    019 59.8 W    27 Jul 88    254.2    457.9
           22    54 29.2 N    020 00.8 W    27 Jul 88    254.2    457.9
           23    53 59.0 N    020 00.8 W    27 Jul 88    254.2    457.9
           24    53 30.0 N    020 00.6 W    28 Jul 88    254.2    457.9
           25    52 59.1 N    020 01.1 W    28 Jul 88    254.2    457.9
           26    52 29.1 N    020 00.3 W    28 Jul 88    254.2    457.9
           27    51 59.1 N    019 59.6 W    28 Jul 88    254.2    457.9
           28    51 29.2 N    020 00.9 W    28 Jul 88    254.2    457.9
           29    50 58.9 N    019 59.9 W    29 Jul 88    254.2    457.9
           30    50 28.4 N    020 01.3 W    29 Jul 88    254.2    457.9
           31    50 04.6 N    019 59.4 W    29 Jul 88    254.2    457.9
           32    49 28.1 N    020 00.2 W    29 Jul 88    254.2    458.0
           33    48 58.7 N    020 00.7 W    29 Jul 88    253.4    457.9
           34    48 30.3 N    019 59.6 W    30 Jul 88    253.4    457.9
           35    47 59.8 N    020 00.6 W    30 Jul 88    253.4    457.9
           36    47 29.2 N    020 01.4 W    30 Jul 88    253.4    457.9
           37    46 59.3 N    019 59.4 W    30 Jul 88    252.9    457.6
           38    46 29.4 N    019 58.4 W    30 Jul 88    253.1    457.6
           39    45 58.8 N    020 00.2 W    31 Jul 88    253.1    457.6
          
          TABLE 3 (cont.)
                                                         F11      F12
          STN    LATITUDE     LONGITUDE     DATE         PPT      PPT
          ---    ---------    ----------    ---------    -----    -----
           40    45 29.1 N    020 00.7 W    31 Jul 88    253.1    457.6
           41    44 59.4 N    019 59.7 W    31 Jul 88    253.1    457.6
           42    44 29.6 N    019 59.6 W    31 Jul 88    253.1    457.6
           43    43 59.8 N    019 59.1 W     1 Aug 88    253.1    457.6
           44    43 29.7 N    020 02.5 W     1 Aug 88    253.1    457.6
           45    43 00.1 N    020 01.4 W     1 Aug 88    253.1    457.6
           46    42 30.7 N    020 00.7 W     1 Aug 88    253.1    457.6
           47    42 00.8 N    020 00.5 W     1 Aug 88    252.8    457.9
           48    41 29.9 N    020 01.3 W     2 Aug 88    252.2    458.5
           49    41 00.8 N    019 59.6 W     2 Aug 88    251.4    458.5
           50    40 30.9 N    020 01.8 W     2 Aug 88    251.4    458.5
           51    40 01.1 N    019 59.7 W     2 Aug 88    251.4    458.5
           52    39 31.1 N    020 00.6 W     2 Aug 88    251.4    458.5
           53    38 59.5 N    020 00.8 W     3 Aug 88    251.7    459.6
           54    38 31.6 N    020 02.3 W     3 Aug 88    251.7    459.6
           55    38 01.1 N    019 59.1 W     3 Aug 88    251.7    459.6
           56    37 30.0 N    020 00.3 W     3 Aug 88    251.7    459.6
           57    37 00.2 N    020 00.4 W     4 Aug 88    251.7    459.6
           58    36 29.7 N    020 00.4 W     4 Aug 88    251.4    458.7
           59    36 00.3 N    020 01.4 W     4 Aug 88    251.5    458.7
           60    35 34.9 N    020 16.8 W     4 Aug 88    251.4    458.7
           61    35 05.8 N    020 32.1 W     5 Aug 88    251.4    458.7
           62    34 39.3 N    020 48.7 W     5 Aug 88    251.4    458.7
           63    34 12.9 N    021 04.4 W     6 Aug 88    251.4    458.7
           64    33 45.8 N    021 18.9 W     6 Aug 88    251.4    458.7
           65    33 19.3 N    021 36.4 W     6 Aug 88    251.4    458.7
           66    32 49.9 N    021 52.6 W    11 Aug 88    248.4    459.6
           67    32 23.4 N    022 08.5 W    11 Aug 88    248.4    459.6
           68    31 56.9 N    022 23.8 W    11 Aug 88    248.4    459.6
           69    31 30.0 N    022 41.7 W    12 Aug 88    248.4    459.6
           70    31 03.0 N    022 54.9 W    12 Aug 88    248.4    459.6
           71    30 36.1 N    023 10.4 W    12 Aug 88    248.4    459.6
           72    30 09.1 N    023 24.7 W    12 Aug 88    248.4    459.6
           73    29 29.1 N    023 48.0 W    12 Aug 88    248.4    459.6
           74    28 50.7 N    024 13.0 W    13 Aug 88    248.4    459.6
           75    28 07.2 N    024 30.7 W    13 Aug 88    248.4    459.6
           76    27 25.1 N    024 55.5 W    13 Aug 88    248.4    459.6
           77    26 44.9 N    025 16.5 W    13 Aug 88    248.4    459.6
           78    26 02.1 N    025 49.5 W    14 Aug 88    248.4    459.6
           79    25 23.4 N    026 00.2 W    14 Aug 88    248.4    459.6
          
          TABLE 3 (cont.)
                                                         F11      F12
          STN    LATITUDE     LONGITUDE     DATE         PPT      PPT
          ---    ---------    ----------    ---------    -----    -----
           80    24 43.9 N    026 21.1 W    14 Aug 88    248.4    459.6
           81    24 00.2 N    026 54.7 W    14 Aug 88    248.4    459.6
           82    23 23.8 N    027 05.5 W    15 Aug 88    248.4    459.6
           83    22 43.6 N    027 28.6 W    15 Aug 88    248.4    459.6
           84    22 04.3 N    027 51.1 W    15 Aug 88    248.4    459.6
           85    21 22.7 N    028 14.8 W    15 Aug 88    248.4    459.6
           86    20 41.0 N    028 36.7 W    16 Aug 88    243.4    450.4
           87    20 00.4 N    029 00.9 W    16 Aug 88    243.4    450.4
           88    19 15.4 N    029 00.2 W    16 Aug 88    243.4    450.4
           89    18 30.7 N    029 00.6 W    16 Aug 88    243.4    450.4
           90    17 44.9 N    029 00.5 W    17 Aug 88    243.4    450.4
           91    17 01.0 N    028 59.9 W    17 Aug 88    241.0    446.7
           92    16 15.3 N    028 56.7 W    17 Aug 88    239.6    444.8
           93    15 30.7 N    029 00.3 W    17 Aug 88    239.6    444.8
           94    14 45.4 N    029 01.1 W    17 Aug 88    237.6    442.0
           95    14 00.1 N    029 00.0 W    18 Aug 88    237.6    442.0
           96    13 15.7 N    029 00.7 W    18 Aug 88    235.9    440.0
           97    12 29.6 N    028 59.3 W    18 Aug 88    234.3    438.3
           98    11 45.6 N    028 59.1 W    18 Aug 88    234.3    438.3
           99    10 59.2 N    028 59.4 W    19 Aug 88    234.3    438.3
          100    10 17.5 N    028 40.9 W    19 Aug 88    234.3    438.3
          101    09 35.3 N    028 24.2 W    19 Aug 88    234.3    438.3
          102    08 55.7 N    028 05.8 W    19 Aug 88    234.3    438.3
          103    08 13.5 N    027 49.3 W    20 Aug 88    234.3    438.3
          104    07 32.2 N    027 31.4 W    20 Aug 88    234.3    438.3
          105    06 50.1 N    027 15.2 W    20 Aug 88    234.3    438.3
          106    06 09.3 N    026 55.9 W    20 Aug 88    233.4    437.1
          107    05 27.6 N    026 40.0 W    21 Aug 88    233.4    437.1
          108    04 46.1 N    026 23.8 W    21 Aug 88    233.4    437.1
          109    04 03.9 N    026 04.5 W    21 Aug 88    233.2    437.5
          110    03 24.5 N    025 39.8 W    21 Aug 88    233.2    437.5
          111    02 41.5 N    025 29.8 W    22 Aug 88    233.2    437.5
          112    02 00.2 N    025 12.9 W    22 Aug 88    233.2    437.5
          113    01 25.9 N    025 00.9 W    22 Aug 88    233.4    436.1
          114    01 00.2 N    025 00.2 W    22 Aug 88    233.8    436.2
          115    00 39.4 N    024 58.7 W    22 Aug 88    233.8    436.2
          116    00 20.0 N    025 00.1 W    23 Aug 88    233.8    436.2
          117    00 00.3 N    024 59.8 W    23 Aug 88    233.8    436.2
          118    00 19.9 S    025 00.8 W    23 Aug 88    233.8    436.2
          119    00 40.1 S    025 00.0 W    23 Aug 88    233.8    436.2
          120    01 00.1 S    025 00.3 W    23 Aug 88    233.8    436.2
          121    01 30.2 S    024 59.8 W    23 Aug 88    233.8    436.2
          122    02 00.3 S    024 59.2 W    24 Aug 88    233.8    436.2
          123    02 37.8 S    024 59.8 W    24 Aug 88    233.8    436.2
          124    03 01.7 S    024 58.8 W    24 Aug 88    233.8    436.2
          125    10 02.0 N    022 08.0 W    27 Aug 88    233.4    437.1
          126    10 29.0 N    022 04.0 W    27 Aug 88    233.4    437.1
          127    10 58.0 N    021 57.0 W    27 Aug 88    233.4    437.1
          128    11 27.3 N    021 51.5 W    27 Aug 88    233.4    437.1
          129    11 57.0 N    021 44.0 W    27 Aug 88    233.4    437.1
          
          
          
          
          ___________________________________________________________________________________________________________
          ___________________________________________________________________________________________________________
          
          
          
          
          APPENDIX A:  CTD PROCESSING NOTES
          
          *NOTE:  All casts are down-cast 2-decibar pressure-series data, unless 
                  otherwise noted*
          
          STN  CAST  REMARKS
          ---  ----  -------------------------------------------------------------
            1   1    0-dbar level extrapolated
            2   1
            3   1
            4   1
            5   1
            6   1
            7   1    0-dbar level extrapolated
            8   1    0-dbar level extrapolated
            9   1    0-dbar level extrapolated
           10   1    up cast; signal problems: lost signal/gaps, down and up
                     13 levels (1916 of data) missing
                     6 single levels interpolated:
                     1298, 1306, 1318, 1344, 1542, 2430 dbars
                     2 multiple levels interpolated:
                      1550 thru 1552 dbars (2 consecutive levels)
                      1568 thru 1576 dbars (5 consecutive levels)
           11   2    new end termination prior to aborted cast 1; data begins 
                       after in water (6 dbars); signal dropouts down from 1330 
                       dbars, major signal dropouts below 2000 dbars down and up; 
                     no bottles above 500 dbars
                     71 levels (5% of data) missing
                     3 single levels interpolated:
                       2106,2438, 2700 dbars
                     10 multiple levels extrapolated/interpolated-
                          0 thru.    2 dbars  (2 consecutive levels)
                        686 thru.  690 dbars  (3 consecutive levels)
                       1342 thru. 1344 dbars  (2 consecutive levels)
                       1348 thru. 1362 dbars  (8 consecutive levels)
                       1366 thru. 1374 dbars  (5 consecutive levels)
                       1828 thru. 1940 dbars  (7 consecutive levels)
                       1982 thru. 2028 dbars (24 consecutive levels)
                       2034 thru. 2044 dbars  (6 consecutive levels)
                       2082 thru. 2094 dbars  (7 consecutive levels)
                       2114 thru. 2116 dbars  (2 consecutive levels)
                       2694 thru. 2696 dbars  (2 consecutive levels)
           12   1    0-dbar level extrapolated; repaired pylon prior to cast; new 
                     end termination
           13   1    0-dbar level extrapolated
           14   1
           15   1
           16   1
           17   1
           18        rosette and pylon replaced prior to cast
           19   1
           20   1
           21   1    rosette hit bottom after bottom trip
           22   1
           23   1
           24   1    0-dbar level extrapolated
           25   1    0-dbar level extrapolated
           26   1    0-dbar level extrapolated; 470-dbar level interpolated
           27   1
           28   1    0-dbar level extrapolated
           29   1
          
          STN  CAST  REMARKS
          ---  ----  -------------------------------------------------------------
           30   1    pylon problems, top 8 bottles did not trip
           31   1    pylon changed prior to cast
           32   1    0-dbar level extrapolated
           33   1    0-dbar level extrapolated, data begins after cast in water 
                      (3 dbars)
           34   1    0-dbar level extrapolated; pinger signal weak
           35   1    0-12 dbars: (7 consec. levels) extrapolated, data begins 
                     after in water (14 dbars); 1278-dbar level interpolated; 20-
                     minute stop at 3640 dbars
           36   1    0-dbar level extrapolated
           37   1
           38   1    0-dbar level extrapolated
           39   1    0-dbar level extrapolated
           40   1    no pinger, used altimeter for bottom reading
           41   1    0-2 dbars (2 consec. levels) extrapolated, data begins after 
                     in water (4 dbars); CTD signal losses up
           42   1    0-dbar level extrapolated; CTD signal losses upcast
           43   1
           44   1    0-dbar level extrapolated
           45   1
           46   1    0-dbar level extrapolated
           47   1
           48   1
           49   1    0-dbar level extrapolated; CTD signal losses upcast
           50   1
           51   1    multiple CTD signal losses upcast
           52   1    0-dbar level extrapolated; CTD signal losses upcast
           53   1
           54   1    0-dbar level extrapolated; 1098-1102 dbars (3 consec. 
                     levels) interpolated power surge problems; yoyo at 1190 to 
                     1114 dbars down, winch problems, winch test at 2045 dbars 
                     down 3-min. stop
           55   1    yoyos at 24 dbars to near-surface down
           56   1
           57   1    0-dbar level extrapolated; sea turtle observing upcast
           58   1
           59   1    0-dbar level extrapolated, data begins after cast in water 
                     (3 dbars); 1034-dbar level interpolated
           60   1    5344-dbar and 5348-dbar levels interpolated; winch slipping 
                     on upcast
           61   1    no battles above 1180 dbars; unusual low CTD oxygen area 
                     1450-2750 dbars
           61   2
           62   1    CTD signal losses upcast; no bottles above 1310 dbars
           62   2
           63   1    0-dbar level extrapolated; no bottles above 1060 dbars
           63   2
           64   1
           65   1
           65   2    0-dbar level extrapolated; first cast in 5 days, following 
                     port-stop conductivity sensor probably not soaked before 
                     cast
           66   1    0-dbar level extrapolated; small CTD oxygen inversion where 
                     pauses at 5200 dbars down
           67   1
           68   1
           69   1    0-dbar level extrapolated; new end termination; CTD oxygen 
                     inversion
                     1820-1940 dbars down, origin unknown; short in cable to 
                     slip-rings discovered after cast; transmiss. shifted at this 
                     cast
           70   1
          
          STN  CAST  REMARKS
          ---  ----  -------------------------------------------------------------
           71   1    CTD signal losses upcast
           72   1
           73   1
           74   1
           75   1    0-dbar level extrapolated; CTD signal losses upcast
           76   1    CTD signal losses upcast
           77   1
           78   1
           79   1    0-dbar level extrapolated
           80   1    CTD signal losses upcast
           81   1
           82   1    CTD signal losses upcast
           83   1    CTD signal losses upcast
           84   1    CTD signal losses upcast
           85   1    CTD signal losses upcast
           86   1    CTD oxygen offset 2150 dbars: down, origin unknown
           87   1    0-dbar level extrapolated
           88   1    0-dbar level extrapolated; 3-minute stop at 2045 dbars down; 
                     change trip-box mid-upcast no voltage
           89   1    winch problems: stop 7/9 minutes at 1625/1750 dbars down
           90   1    winch problem: stop 10 minutes at 2245 dbars down
           91   1
           92   1    winch stopped 6 minutes at 900 dbars down; winch testing 
                     during upcast
           93   1
           94   1    0-dbar level extrapolated
           95   1    0-dbar level extrapolated
           96   1
           97   1    0-dbar level extrapolated; 1734-dbar level interpolated
           98   1    winch slipping on upcast
           99   1
          100   1    stop 8 minutes at 4665 dbars down to throw circuit breaker 
                     (winch?)
          101   1
          102   1
          103   1
          104   1
          105   1
          106   1
          107   1    0-dbar level extrapolated
          108   1
          109   1    0-dbar level extrapolated
          110   1
          111   1    0-dbar level extrapolated
          112   1    lost signal at 2500 dbars down, deck unit problems
                     78 levels (4% of data) missing
                     8 single levels interpolated:
                       2766, 3154, 3388, 3416, 3438, 3490, 3852, 3860 dbars
                     7 multiple levels interpolated:
                       2318 thru. 2424 dbars (54 consecutive levels)
                       2760 thru. 2762 dbars  (2 consecutive levels)
                       3410 thru. 3412 dbars  (2 consecutive levels)
                       3498 thru. 3506 dbars  (5 consecutive levels)
                       3510 thru. 3514 dbars  (3 consecutive levels)
                       3520 thru. 3522 dbars  (2 consecutive levels)
                       3880 thru. 3882 dbars  (2 consecutive levels)
          113   1    0-dbar level extrapolated; winch slipping on upcast
          114   1    CTD signal losses upcast
          115   1    up cast; 0-dbar level extrapolated; 2252-2254 dbars (2 
                     consec. levels) interpolated; deck unit/CTD signal problems 
                     at 2164 dbars down
          116   1    0-dbar level extrapolated; winch slipping on upcast
          117   1    0-dbar level extrapolated; EQUATOR
          118   1    0-dbar level extrapolated; CTD signal losses upcast
          119   1
          120   1    0-dbar level extrapolated
          121   1    change to transmiss. #100D before cast
          122   1    0-dbar level extrapolated
          123   1    1280-dbar and 2444-dbar levels interpolated
          124   1    0-dbar level extrapolated; 4776-dbar level interpolated
          125   1    up cast; new end termination; recording/signal problems 
                     until 2525 dbars down; transmiss. signal shifted "back" this 
                       (diff. transmiss. than sta. 69) poor fit in bottom 500 
                     dbars of CTD oxygen (upcast)
          126   1
          127   1    no bottles above 3830 dbars (planned/deep multi-trips)
          128   1    0-dbar level extrapolated
          129   1
          
          
          
          
          ___________________________________________________________________________________________________________
          ___________________________________________________________________________________________________________
          
          
          
          
          APPENDIX B:  REMARKS FOR DELETED OR MISSING SAMPLES 
          
          Investigation of data may include comparison of bottle salinity and oxygen with 
          CTD data, review of data plots of station profile and adjoining stations. CTD 
          data is reported instead of bottle salinity when the comments refer to deleted 
          salinity samples or no samples. There was a problem with the shies wire which 
          caused many of the tripping problems. There was also a problem with temperature 
          control in the van where the salinity analysis occurred. This caused many of the 
          problems with salinity. Extra levels may occur for each station. These levels 
          were extracted from CTD data for purposes of reporting deepest sampling level.
          
          Station 001
          
               106-17  Sample log: No salinity or oxygen per sampling schedule. 
                       Duplicates @ 120db include water samples; therefore CTD trip 
                       information for these 12 bottles deleted. No nutrients or 
                       freon sampled.
                  119  delta-S .006 @ 120db, sample high as compared with duplicate 
                       samples. Oxygen agrees with CTD and duplicates. Suspect 
                       salinity problem with drawing or analysis. Delete salinity 
                       sample (35.139).
                  120  Sample log: No salinity or oxygen per sampling schedule. 
                       Duplicates @ 120db that include water samples; therefore CTD 
                       trip information deleted. No nutrients or freon sampled.
          
          STATION 003
          
                  102  Sample log: Not closed, no water. Level not included in data tables, 
                       not necessary duplicate @8db.
                  119  delta-S @820db is .059. Salinity was 35.110, salt bottle #3813. Oxygen 
                       fits station profile. Bottle could have leaked, salinity and oxygen 
                       value could fit higher in the water column, but for now, will assume 
                       that there was only a problem with salinity. Delete salinity value.
          
          STATION 004
          
                  117  delta-S @810db is .060. Salinity was 35.065, salt bottle #3636. 
                       Appears to be a sampling error, value close to shallower 
                       level. Oxygen agrees with station profile- Delete salinity 
                       value leave oxygen 
                  124  Sample log: Bottle drained before salinity was sampled. CTD 
                       salinity @ 1246db reported.
          
          STATION 005
          
                  122  delta-S @ 1293db is .0060. Salinity is 34.993; salt bottle 
                       #3526. The first inclination was to leave salinity data; 
                       there are salinity changes reflected in CTD data. Salinity @ 
                       1293db shows slight deviation from the distribution at 
                       adjoining stations. - M. Tsuchiya. After further review and 
                       from the comments by M. Tsuchiya; delete salinity value.
          
          STATION 007
          
               101-08  Sample log: Tripping problems, no water samples. CTD 
                       data reported to augment temperature and salinity profile. 
                       CTD data level not necessary, duplicate @ 357db. 
          
          STATION 008
          
                  107  Sample log: Was not tripped. CTD data level not necessary, 
                       duplicate @ 3db.
                  108  Sample log: Was not tripped. Use surface CTD data @3db.
          
          STATION 010
          
                  101  No confirm for CTD trip at surface. Did not get CTD data; 
                       bottle not sampled.
                  108  Sample log: No sample per sampling schedule. Duplicate trip 
                       @506db, level not necessary.
                  112  Salinity (34.962) @ 1063db deleted because of CTD 
                       difference.
                  113  delta-S @ 1214db is .0057. Salt bottle #3327. Oxygen looks good. 
                       Delete salinity (34.926).
                  114  Salinity (34.931) @ 1366db deleted because of CTD 
                       difference.
                  117  Salinity (34.928) @ 1820db deleted because of CTD 
                       difference.
          
          STATION 011
          
               201-12  No water samples taken. CTD data reported from surface to 
                       407db to augment temperature and salinity profile.
                  202  Delete duplicate CTD data @ 106db.
                  213  delta-S @506db is .0108. Salt bottle #e76. Duplicate trip at 
                       this level which agrees with CTD data. Other parameters 
                       agree well with duplicates. Delete bottle salinity (35.093).
          
          STATION 013
          
                  108  Sample log: Bottom O-ring pinched, leaky pushed back in to 
                       sample. Short salt Salinity and oxygen @508db fits station 
                       profile. Oxygen a little low compared with adjacent 
                       stations. Principal Investigator (L.T.) deleted nutrients. 
                       Footnote salinity and oxygen uncertain.
          
          STATION 015
          
                  119  Oxygen: Ship roll got sample. No oxygen sample @ 1111db.
          
          
          STATION 017
          
                  119  Sample log: Bottle dry, no samples. CTD data reported @506db to 
                       augment temperature and salinity profile.
          
          STATION 018
          
                  117  Sample log: Bottom lanyard from #18 caught. No water 
                       samples. CTD data reported @699db to augment temperature and 
                       salinity profile.
          
          STATION 019
          
                  103  No samples drawn, triplicate @9db therefore CTD data not 
                       necessary.
          
          STATION 022
          
               105-09  No water samples taken, duplicate trips @5db; therefore CTD 
                       data not necessary.
          
          STATION 024
          
                  101  Sample log: Not closed. Duplicate trip @9db therefore CTD 
                       data not necessary.
          
          STATION 025
          
                  122  delta-S @2317db is -.0175. All other parameters fit station 
                       profile, suspect a sampling error. Delete bottle salinity 
                       (34.936).
          
          STATION 026
          
                  123  delta-S @2536db is -.0047. Salt bottle #3498. All other water 
                       parameters agree with duplicate level. Delete bottle 
                       salinity (34.950), suspect analysis problem. Analysts 
                       indicated ship roll.
          
          STATION 030
          
               101-08  Sample log: No water, ramp shaft stuck on #9. CTD data 
                       report @ 10db to augment temperature and salinity profile.
          
          STATION 031
          
                  121  delta-S is -.0046 @3538db. Suspect some analysis or drawing 
                       problem. Delete bottle salinity.
          
          STATION 039
          
                  111  Salinity @840db is missing, no reason on salinity sheet.
          
          STATION 040
          
                  101  Sample log: Leaked when rosette was brought out of water. 
                       Salinity was not drawn @5db; oxygen is reasonable.
                  107  delta-S @510db is -.0199. Salt bottle #3049. Suspect drawing 
                       error. Delete bottle salinity (35.408).
                  124  delta-S @4610db is .0037. Salt bottle #3078. Suspect analysis 
                       error. Delete bottle salinity (34.913).
          
          STATION 041
          
                  107  delta-S @300db is -.0193. Salt #48kk. Deviates from adjacent 
                       station comparison. Delete bottle salinity (35.624).
          
          STATION 043
          
                  121  Salinity (34.957) deleted because of CTD difference. This 
                       could have been a sampling error @ 3288db with # 19 @2760db.
                  122  Sample log: No water left for nutrients. No nutrient samples 
                       @3609db.
          
          STATION 044
          
                  114  Salinity: Salt Bottle #16z leaky (removed). delta-S @ 1269db is 
                       .0058. Delete bottle salinity (35.161).
                  121  delta-S @3204db is .0040. Salinity: Leaker - salt bottle #3526. 
                       Delete bottle salinity (34.941).
          
          STATION 048
          
                  120  delta-S @1810db is .0044. 34.993; salt bottle #3398. Delete 
                       bottle salinity.
                  121  delta-S @2015db is .0044. Salinity was 34.983; salt bottle 
                       #3908. Delete bottle salinity.
                  124  delta-S @2540db is .0044. Salinity was 34.958; salt bottle 
                       #3608. Delete bottle salinity.
          
          STATION 049
          
                  124  Oxygen (5.54) @4771db deleted because sample pickled late.
          
          STATION 052
          
                  116  delta-S @2049db is -.0045. Salinity was 35.055, salt bottle #76k 
                       Console ops: CTD moved before trip. Suspect this means that 
                       water samples were contaminated. Delete salinity and oxygen 
                       samples (5.91).
          
          STATION 055
          
                  116  Oxygen: May be high, forgot to add acid before stirring. 
                       Oxygen (6.02) @2562db deleted.
          
          STATION 056
          
                  124  Sample log: Upper lid hung up on cross bar, did not close, 
                       no sample. CTD data @491ldb reported to augment temperature 
                       and salinity profile.
          
          STATION 057
          
                  101  Sample log: Bottle not tripped-malfunction. Surface sample 
                       @11db; therefore CTD data level not necessary.
                  102  Sample log: Bottle not tripped-malfunction. Surface sample 
                       @11db; therefore CTD data level not necessary.
                  103  Sample log: Bottle not tripped-malfunction. Surface sample 
                       @11db, therefore CTD data level not necessary.
          
          STATION 058
          
                  101  Sample log: No sample, ramp shaft looks like it is caught 
                       between #1 and #2. CTD data reported @ 3db to augment 
                       station temperature and salinity profile.
          
          STATION 059
          
                  101  Sample log: Did not fire. CTD data reported @14db to augment 
                       station temperature and salinity profile.
                  102  Salt (35.464) deleted @39db, bad but reason unknown. Oxygen 
                       ok.
          
          STATION 061
          
               101-11  Sample log: Did not trip.
                  119  Sample log: Lanyard caught in bottom lid, bad leak when 
                       spigot opened. Salt (35.796), oxygen (5.15) deleted because 
                       bottle apparently leaked @3601db.
               201-08  Water samples were not taken from these bottles. Data 
                       reported for surface from bottle 9 @4db.
          
          STATION 062
          
               101-11  Sample log: Did not trip, wire problems.
                  116  Salinity (35.755), oxygen (5.18) @2524db deleted because 
                       lanyard caught in bottom lid.
                  201  Sample log: G-ring pinched in bottom lid - leaky. Salinity 
                       (35.648). oxygen (4.73) @1197db deleted because battle 
                       leaked. CTD data not included, duplicate with samples @3db.
               202-08  No bottles tripped.
          
          STATION 063
          
               101-11  Sample log: Trip problems, no fire. CTD data reported to 
                       augment station profile for temperature and salinity.
                  112  Oxygen @ 1060db deleted because of analyst. Oxygen (5.20) 
                       too high.
                  202  Sample log: Did not trip. Surface value @ 10db reported with 
                       bottle 4 data.
                  203  Sample log: Did not trip. Surface value @ 10db reported with 
                       bottle 4 data.
          
          STATION 064
          
                  101  delta-S @5204db is .0064. Salinity was 34.894; salt bottle 
                       #3135. Slightly high as compared with adjacent stations. 
                       Oxygen appears a little high but agrees with next station, 
                       but also high compared with previous station. Delete 
                       salinity.
                  102  Sample log: Did not trip. CTD data not reported.
                  103  Sample log: Did not trip. CTD data not reported.
          
          STATION 065
          
                  102  Sample log: Did not trip. No bottle information necessary, 
                       no samples taken.
                  103  Sample log: Did not trip. No bottle information necessary, 
                       no samples taken.
                  106  delta-S @ 159db is -.1585. Leave oxygen value, delete bottle 
                       salinity, 36.028.
                  118  Salinity @2914db .02 low, looks like a sampling error. 
                       Oxygen and nutrients okay. Delete bottle salinity, 34.921.
               201-24  No salts, deck crew did not realize salts had not been drawn 
                       and drained niskin bottles in preparation of next cast.
          
          STATION 067
          
                  101  Sample log: Did not trip. CTD data not necessary for station 
                       profile.
                  102  Sample log: Did not trip. CTD data not necessary for station 
                       profile.
                  103  Sample log: Did not trip. CTD data not necessary for station 
                       profile.
          
          STATION 069
          
               101-06  Sample log: Did not close, tripping problem. Surface data 
                       from bottles 7 & 8 @12db, therefore these bottle numbers 
                       were not used.
                  109  Oxygen @37db appears high. Does not agree with CTD data. 
                       Delete bottle oxygen (5.85).
          
          STATION 070
          
                  101  Sample log: Bottle did not close. No water samples, CTD data 
                       not reported.
          
          STATION 071
          
                  101  Bottle did not trip. No water samples, CTD data not 
                       reported.
          
          STATION 075
          
                  106  Sample log: Feels warmer than #5. Salinity (36.679) and 
                       oxygen (4.80) deleted @5319db because of pre or post trip.
          
          STATION 078
          
                  115  Sample log: Bottle empty after SF6 drawn no salinity or 
                       oxygen. CTD salinity reported @587db, duplicate. Level 
                       necessary for Freon shore-based samples.
          
          STATION 081
          
                  113  Sample log: Lower lid leaking-maybe O-ring out of groove. 
                       Not enough water for salts, therefore CTD salinity reported. 
                       Oxygen @ 310db looks okay.
                  116  Sample log: Lanyard in lower lid, no samples. CTD data 
                       reported @810db to augment temperature and salinity profile.
          
          STATION 083 
          
                  104  delta-S @4892db is .0061. Salinity was 34.892; salt bottle #15a. 
                       Delete salinity, oxygen appears to be okay.
          
          STATION 085 
          
                  106  Oxygen data analyst suspects this sample @5384db is high. 
                       Delete high oxygen (5.67), salinity looks okay.
                  117  Oxygen @1045db appears to be too high. Value agrees with 
                       118; suspect drawing error. Delete value of 4.37; 31 July 
                       1990.
          
          STATION 086 
          
                  104  delta-S @4737db is .0068. Salinity was 34.893; salt bottle #15a. 
                       This salinity bottle was found to be leaking. Delete 
                       salinity.
                  122  delta-S @2496db is .0043. Salinity was 34.981; salt bottle #t86. 
                       Delete salinity; suspect an analysis problem.
          
          STATION 090 
          
                  103  delta-S @3662db is -.0043. Salinity was 34.899; salt bottle 
                       #4508. Delete salinity, oxygen and nutrients look 
                       reasonable, probably analysis error or poor sampling.
          
          STATION 093 
          
                  102  Sample log: Leak around bottom lid, samples not taken. CTD 
                       data reported @40db to augment temperature and salinity 
                       profile.
          
          STATION 094 
          
                  123  Oxygen (5.74) @5240db deleted because of stirring problem. 
                       Oxygen: Poor stirring, two stir bars.
          
          STATION 100 
          
                  112  delta-S @985db is .053. Salinity was 34.766; salt bottle #3694. 
                       Oxygen is a little high as compared with CTD data. Delete 
                       salinity and oxygen (3.12), this bottle had a large 
                       difference on Stations 106 and 100 also.
          
          STATION 103 
          
                  122  Salt (34.902) deleted @3814db because of bad salt bottle 
                       (15a).
          
          STATION 105 
          
                  112  delta-S @913db is .0792. Salinity was 34.715; salt bottle #3694. 
                       Oxygen looks reasonable agrees with CTD data. Delete 
                       salinity, this bottle had a large difference on stations 106 
                       and 100 also.
          
          STATION 106 
          
                  112  delta-S @ 702db is .0594. Salinity was 34.688; salt bottle 
                       #3986. CTD indicates salinity minimum for 700 db. Other 
                       parameters look good, contamination must only be in 
                       salinity. Delete salinity.
          
          STATION 107 
          
                  107  Sample log: Bottle did not close - ramp shaft is in correct 
                       position. Some biological stuff on rosette. CTD data @247db 
                       reported to augment temperature and salinity profile.
                  122  Salinity (34.898) @3910db deleted because of bad salt bottle 
                       (15a).
          
          STATION 108 
          
                  107  Sample log: Bottle did not fire. No water samples. CTD data 
                       @250db reported to augment temperature and salinity profile.
          
          STATION 113
          
                  117  Sample log: Lanyard in lower lid, no water. CTD data @1164db 
                       reported to augment temperature and salinity profile.
          
          STATION 115 
          
                  107  Sample log: Did not close. CTD data reported @207db to 
                       augment temperature and salinity profile.
          
          STATION 116 
          
                  107  Sample log: Did not close. CTD data reported @207db to 
                       augment temperature and salinity profile.
          
          STATION 118
          
                  107  Sample log: Did not close. CTD data reported @204db to 
                       augment temperature and salinity profile.
          
          STATION 119 
          
                  116  delta-S @ 1403db is .0092. Salinity was 34.939; salt bottle 
                       #3538. Oxygen looks reasonable. Salinity @ 1403db deleted 
                       because water sample only 1/5 full.
          
          STATION 122 
          
                  124  Sample log: Water feels warmer than 23. Oxygen (3.92) and 
                       salinity (35.700) @4999db deleted because bottle leaked. CTD 
                       data reported to augment temperature and salinity profile.
          
          STATION 124 
          
                  106  Sample log: Not enough water for salts. CTD salinity @209db 
                       reported.
          
          STATION 126 
          
                  122  Salinity, 34.883, @4903db deleted because of drift. Salt 
                       bottle #15a which has caused trouble before.
          
          STATION 127 
          
                  123  Oxygen: Bubble in flask. Oxygen @5190db .04 high as compared 
                       with duplicate samples. Delete oxygen sample (5.53).
          
          STATION 129 
          
                  112  Bottle deleted because of suspected leak. Salinity was 
                       34.979, oxygen was 4.24. CTD data reported @ 1476db to 
                       augment temperature and salinity profile.
          
          
          
          
          ___________________________________________________________________________________________________________
          ___________________________________________________________________________________________________________
          
          
          
          STATION AND CAST DESCRIPTIONS
            OCEANUS 202 (McTT)    
            R/V OCEANUS     
            11 JUL- 1 SEP 1988
          
                                                                   MAXIMUM
          STN/               TIME                           OCEAN  SAMPLING  DAB
          CAST    DATE       GMT   LATITUDE    LONGITUDE    DEPTH  DEPTH     M   COMMENTS         SAMPLES
          ------  ---------  ----  ----------  -----------  -----  --------  --- ---------------  -------
            1/01  23 Jul 88  2118  63 19.8'N  019 59.9'W   199    194          *                *F
            2/01  23 Jul 88  2301  63 12.6'N  020 00.3'W   621    627       5  * 16 bottles     *F
            3/01  24 Jul 88  0056  63 08.0'N  020 00.4'W   927    940       7  * 23 bottles     *
            4/01  24 Jul 88  0321  62 59.3'N  020 00.7'W  1237   1231       7  *                *F,H,Tr
            5/01  24 Jul 88  0620  62 40.3'N  019 59.9'W  1481   1480       5  *                *
            6/01  24 Jul 88  0935  62 19.8'N  020 00.1'W  1909   1809       7  * 17 bottles     *F
            7/01  24 Jul 88  1409  61 49.6'N  020 01.3'W  1769   1710      10  *                *
            8/01  24 Jul 88  1825  61 19.6'N  020 00.8'W  2350   2345      12  * 23 bottles     *F
            9/01  24 Jul 88  2257  60 49.5'N  019 58.9'W  2361   2354       8  * 21 bottles     *
           10/01  25 Jul 88  0421  60 19.6'N  019 59.9'W  2619   2610      15  *                *F
           11/01  25 Jul 88  0820  59 50.2'N  019 59.6'W                       * ABORTED        *
           11/02  25 Jul 88  1042  59 50.6'N  019 59.2'W  2730   2721      18  *                *F
           12/01  25 Jul 88  1903  59 23.6'N  019 59.2'W  2765   2760      10  *                *F
           13/01  26 Jul 88  0052  59 49.4'N  020 00.8'W  2866   2866       5  *                *F,H,Tr
           14/01  26 Jul 88  0538  58 22.5'N  020 00.8'W  2163   2160       8  *                *F
           15/01  26 Jul 88  0932  57 59.6'N  020 00.8'W  1660   1659       5  * 21 bottles     *F
           16/01  26 Jul 88  1347  57 29.5'N  020 00.6'W  1158   1163      10  * 19 bottles     *
           17/01  26 Jul 88  1758  56 59.2'N  020 01.2'W   982    977      10  * 17 bottles     *F
           18/01  27 Jul 88  0054  56 29.2'N  020 01.2'W  1366   1363       5  * 21 bottles     *
           19/01  27 Jul 88  0513  55 59.3'N  020 01.8'W  1415   1456      10  * 22 bottles     *
           20/01  27 Jul 88  0929  55 29.3'N  020 00.6'W  1251   1243      10  * 21 bottles     *F,H,Tr
           21/01  27 Jul 88  1408  54 59.1'N  019 59.8'W         1640          * 23 bottles     *
           22/01  27 Jul 88  1850  54 29.2'N  020 00.8'W  1380   1381       5  * 20 bottles     *F
           23/01  27 Jul 88  2248  53 59.0'N  020 00.8'W  1443   1421      10  * 19 bottles     *F
           24/01  28 Jul 88  0320  53 30.0'N  020 00.6'W  2285   2283      10  *                *
           25/01  28 Jul 88  0750  52 59.1'N  020 01.1'W  2695   2700       5  *                *F
           26/01  28 Jul 88  1150  52 29.1'N  020 00.3'W  2813   2810       6  *                *F
           27/01  28 Jul 88  1624  51 59.1'N  019 59.6'W  3727   3731       0  *                *F
           28/01  28 Jul 88  2137  51 29.2'N  020 00.9'W  3638   3632       8  *                *F
           29/01  29 Jul 88  0225  50 58.9'N  019 59.9'W  3633   3640       5  *                *F,H,Tr
           30/01  29 Jul 88  0708  50 28.4'N  020 01.3'W  4039   4007      10  *                *
           31/01  29 Jul 88  1149  50 04.6'N  019 59.4'W  4434   4430      10  *                *
           32/01  29 Jul 88  1717  49 28.1'N  020 00.2'W  3790   3821      10  *                *
           33/01  29 Jul 88  2222  48 58.7'N  020 00.7'W  4401   4391      21  *                *F
           34/01  30 Jul 88  0303  48 30.3'N  019 59.6'W  4018   4028      10  *                *
           35/01  30 Jul 88  0737  47 59.8'N  020 00.6'W  4347   4346          *                *F,Tr
           36/01  30 Jul 88  1221  47 29.2'N  020 01.4'W  4551   4540          *                *
           37/01  30 Jul 88  1716  46 59.3'N  019 59.4'W  4494   4519      10  *                *F
           38/01  30 Jul 88  2229  46 29.4'N  019 58.4'W  4854   4840      10  *                *F,H,Tr
           39/01  31 Jul 88  0546  45 58.8'N  020 00.2'W  4843   4834          *                *
           40/01  31 Jul 88  1053  45 29.1'N  020 00.7'W  4530   4528       8  *(altimeter)     *
           41/01  31 Jul 88  1600  44 59.4'N  019 59.7'W  4398   4355       9  *                *F,H,Tr
           42/01  31 Jul 88  2123  44 29.6'N  019 59.6'W  4213   4210      12  * 23 bottles     *F
           43/01  01 Aug 88  0255  43 59.8'N  019 59.1'W  4029   4004      14  *                *F
           44/01  01 Aug 88  0729  43 29.7'N  020 02.5'W  3958   3993      11  *                *F,H,Tr
           45/01  01 Aug 88  1229  43 00.1'N  020 01.4'W  5163   5248      10  *                *
           46/01  01 Aug 88  1712  42 30.7'N  020 00.7'W  4177   4186          *                *
           47/01  01 Aug 88  2138  42 00.8'N  020 00.5'W  2649   2690      15  *                *F,Tr
           48/01  02 Aug 88  0142  41 29.9'N  020 01.3'W  2514   2508      11  *                *
           49/01  02 Aug 88  0620  41 00.8'N  019 59.6'W  4691   4687      10  *                *F
          
          
                                                                   MAXIMUM
          STN/               TIME                           OCEAN  SAMPLING  DAB
          CAST    DATE       GMT   LATITUDE    LONGITUDE    DEPTH  DEPTH     M   COMMENTS         SAMPLES
          ------  ---------  ----  ----------  -----------  -----  --------  --- ---------------  -------
           50/01  02 Aug 88  1206  41 30.9'N  020 01.8'W  4870   4948      10  *                *F,Tr
           51/01  02 Aug 88  1654  40 01.1'N  019 59.7'W  4655   4777      12  *(altimeter)     *F,Tr
           52/01  02 Aug 88  2228  39 31.1'N  020 00.6'W  4593   4630       9  *                *F
           53/01  03 Aug 88  0451  38 59.5'N  020 00.8'W  4731   4712      10  *                *F,Tr
           54/01  03 Aug 88  1127  38 31.6'N  020 02.3'W  4444   4488      11  *                *
           55/01  03 Aug 88  1654  38 01.1'N  019 59.1'W  5149   5136      10  *                *F
           56/01  03 Aug 88  2158  37 30.0'N  020 00.3'W  4812   4824      10  *                *F,Tr
           57/01  04 Aug 88  0231  37 00.2'N  020 00.4'W  3741   3766      10  *                *
           58/01  04 Aug 88  0710  36 29.7'N  020 00.4'W  5169   5156      10  *                *F
           59/01  04 Aug 88  1156  36 00.3'N  020 01.4'W  5267   5318       9  *                *F,Tr
           60/01  04 Aug 88  1650  35 34.9'N  020 16.8'W  5252   5250       9  *                *
           61/01  04 Aug 88  2300  35 06.0'N  020 33.4'W  5226   5217      10  *                *F
           61/02  05 Aug 88  2023  35 05.8'N  020 32.1'W         1193          *formerly cast11 *
           62/01  05 Aug 88  0515  34 40.4'N  020 48.6'W  5154   5154      10  *                *Tr
           62/02  05 Aug 88  2353  34 39.3'N  020 48.7'W         1186          *formerly cast11 *
           63/01  05 Aug 88  1109  34 12.8'N  020 03.9'W  5231   5227      10  *                *
           63/02  06 Aug 88  0342  34 12.9'N  021 04.4'W         1895          *formerly cast11 *
           64/01  06 Aug 88  0807  33 45.8'N  021 18.9'W  5097   5109      12  *                *F,Tr
           65/01  06 Aug 88  1256  33 19.3'N  021 36.4'W  5304   5297       8  *                *
           65/02  11 Aug 88  0415  32 51.0'N  021 19.9'W         1978          *formerly cast11 *
           66/01  11 Aug 88  0823  32 49.9'N  021 52.6'W  5247   5246       8  *                *
           67/01  11 Aug 88  1305  32 23.4'N  022 08.5'W  5185   5179       9  *                *F,Tr
           68/01  11 Aug 88  1755  31 56.9'N  022 23.8'W  5158   5161       8  *                *
           69/01  12 Aug 88  0004  31 30.0'N  022 41.7'W  5252   5247       8  *                *F
           70/01  12 Aug 88  0458  31 03.0'N  022 54.9'W  5262   5250       8  *                *H,Tr
           71/01  12 Aug 88  0956  30 36.1'N  023 10.4'W  5292   5294       8  *                *
           72/01  12 Aug 88  1437  30 09.1'N  023 24.7'W  5292   5283       9  *                *
           73/01  12 Aug 88  2027  29 29.1'N  023 48.0'W  5215   5217      10  *                *F,H,Tr
           74/01  13 Aug 88  0218  28 50.7'N  024 13.0'W  5215   5217       8  *                *
           75/01  13 Aug 88  0821  28 07.2'N  024 30.7'W  5225   5224      10  *                *
           76/01  13 Aug 88  1415  27 25.1'N  024 55.5'W  5236   5234       8  *                *
           77/01  13 Aug 88  1954  26 44.9'N  025 16.5'W  5153   5168       9  *                *F,H,Tr
           78/01  14 Aug 88  0141  26 02.1'N  025 49.5'W  5246   5272       8  *                *SF6
           79/01  14 Aug 88  0727  25 23.4'N  026 00.2'W  5359   5359       9  *                *
           80/01  14 Aug 88  1307  24 43.9'N  026 21.1'W  5406   5404       8  *                *
           81/01  14 Aug 88  1850  24 00.2'N  026 54.7'W  5448   5444       9  *                *Tr
           82/01  15 Aug 88  0048  23 23.8'N  027 05.5'W  5501   5501       8  *                *
           83/01  15 Aug 88  0654  22 43.6'N  027 28.6'W  5516   5511       9  *                *
           84/01  15 Aug 88  1254  22 04.3'N  027 51.1'W  5449   5450       8  *                *
           85/01  15 Aug 88  1848  21 22.7'N  028 14.8'W  5190   5289       8  *                *F,H,Tr
           86/01  16 Aug 88  0057  20 41.0'N  028 36.7'W  5165   5166       8  *                *F
           87/01  16 Aug 88  0646  20 00.4'N  029 00.9'W  4794   4790       8  *                *
           88/01  16 Aug 88  1231  19 15.4'N  029 00.2'W  4517   4524       8  *                *
           89/01  16 Aug 88  1845  18 30.7'N  029 00.6'W  4671   4659       9  *                *H,Tr
           90/01  17 Aug 88  0038  17 44.9'N  029 00.5'W         4408       9  *                *
           91/01  17 Aug 88  0622  17 01.0'N  028 59.9'W  4871   4867       8  *                *
           92/01  17 Aug 88  1214  16 15.3'N  028 56.7'W  5108   5103       8  *                *
           93/01  17 Aug 88  1800  15 30.7'N  029 00.3'W  5252   5249       9  *                *H,Tr
           94/01  17 Aug 88  2352  14 45.4'N  029 01.1'W  5299   5342      10  *                *
           95/01  18 Aug 88  0545  14 00.1'N  029 00.0'W  5439   5433      11  *                *
           96/01  18 Aug 88  1147  13 15.7'N  029 00.7'W  5522   5628      10  *                *
           97/01  18 Aug 88  1741  12 29.6'N  028 59.3'W  5496   5507       8  *                *Tr
           98/01  18 Aug 88  2338  11 45.6'N  028 59.1'W  5729   5728      10  *                *
           99/01  19 Aug 88  0546  10 59.2'N  028 59.4'W  5959   5957      10  *                *
          
          
                                                                   MAXIMUM
          STN/               TIME                           OCEAN  SAMPLING  DAB
          CAST    DATE       GMT   LATITUDE    LONGITUDE    DEPTH  DEPTH     M   COMMENTS         SAMPLES
          ------  ---------  ----  ----------  -----------  -----  --------  --- ---------------  -------
          100/01  19 Aug 88  1150  10 17.5'N  028 40.9'W  5755   5706      10  *                *
          101/01  19 Aug 88  1747  09 35.3'N  028 24.2'W  5517   5536       8  *                *Tr
          102/01  19 Aug 88  2339  08 55.7'N  028 05.8'W  4987   4999      10  *                *
          103/01  20 Aug 88  0521  08 13.5'N  027 49.3'W  4230   4205       9  *                *
          104/01  20 Aug 88  1106  07 32.2'N  027 31.4'W  4230   4195      10  *                *
          105/01  20 Aug 88  1659  06 50.1'N  027 15.2'W  4219   4216       8  *                *Tr
          106/01  20 Aug 88  2240  06 09.3'N  026 55.9'W  4614   4607       9  *                *
          107/01  21 Aug 88  0422  05 27.6'N  026 40.0'W  4358   4362       9  *                *
          108/01  21 Aug 88  1015  04 46.1'N  026 23.8'W  4307   4204       9  *                *deltaN15
          109/01  21 Aug 88  1614  04 03.9'N  026 04.5'W         4496      10  *                *H
          110/01  21 Aug 88  2204  03 24.5'N  025 39.8'W  4340   4340       9  *                *
          111/01  22 Aug 88  0404  02 41.5'N  025 29.8'W  4199   4186       9  *                *
          112/01  22 Aug 88  0952  02 00.2'N  025 12.9'W  3878   3874       9  *                *F
          113/01  22 Aug 88  1552  01 25.9'N  025 00.9'W  1960   2034      10  *                *H
          114/01  22 Aug 88  1924  01 00.2'N  025 00.2'W  3054   3161       9  *                *
          115/01  22 Aug 88  2325  00 39.4'N  024 58.7'W  4250   4269       9  *                *Tr
          116/01  23 Aug 88  0251  00 20.0'N  025 00.1'W  3572   3584       8  *                *
          117/01  23 Aug 88  0602  00 00.3'N  024 59.8'W  3049   3165       9  *                *H,Tr
          118/01  23 Aug 88  0915  00 19.9'S  025 00.8'W  3005   3093       9  *                *
          119/01  23 Aug 88  1222  00 40.1'S  025 00.0'W  3213   3234       8  *                *Tr
          120/01  23 Aug 88  1525  01 00.1'S  025 00.3'W  3067   3188       8  *                *
          121/01  23 Aug 88  2012  01 30.2'S  024 59.8'W  4743   4760       9  *                *H,Tr
          122/01  24 Aug 88  0041  02 00.3'S  024 59.2'W  4922   4919       8  *                *
          123/01  24 Aug 88  0638  02 37.8'S  024 59.8'W  5431   5430       9  *                *
          124/01  24 Aug 88  1243  03 01.7'S  024 58.8'W  5540   5543       5  *                *H
          125/01  27 Aug 88  0500  10 02.0'N  022 08.0'W  5026   5026       8  *                *
          126/01  27 Aug 88  0937  10 29.0'N  022 04.0'W  5140   5136       8  *                *
          127/01  27 Aug 88  1403  10 58.0'N  021 57.0'W  5103   5101       8  *                *
          128/01  27 Aug 88  1819  11 27.3'N  021 51.5'W  5031   5029       8  *                *
          129/01  27 Aug 88  2238  11 57.0'N  021 44.0'W  4954   4950       9  *                *
          ---------------------------------------------------------------------------------------------------
                             F   Freon         Samples for salinity, oxygen and nutrients
                             Tr  Tritium            were collected at every station.
                             H   Helium
          
          
          
          
          ___________________________________________________________________________________________________________
          ___________________________________________________________________________________________________________
          
          
          
          
          LIST OF PARTICIPANTS
          
          Michael McCartney   WHOI  Chief Scientist:     
          Lynne Talley        SIO:  Co-Chief Scientist  23 JUL - 9 AUG 1988
          Mizuki Tsuchiya     SIO   Co-chief Scientist   9 AUG - 1 SEP 1988 
          Paul Howland        WHOI  Ship's Captain:      
          
          Frederick Bingham   SIO
          John Bullister      WHOI
          Nancy Collins       SIO
          Ruth Curry          WHOI
          Frank M. Delahoyde  ODF/SIO  
          Scott Doney         WHOI
          Lee Goodell         ODF
          Joe Jennings        ODF
          Chris Johnston      WHOI
          Leonard Lopez       ODF/SIO
          Forrest K. Mansir   ODF/SIO
          Ronald G. Patrick   ODF/SIO
          Kean Stump          ODF
          Robert T. Williams  ODF/SIO
          
                        ODF:  Oceanographic Data Facility
                        OSU:  Oregon State University:
                        SIO:  Scripps Institution of Oceanography:
                       WHOI:  Woods Hole Oceanographic Institution:

          
          ___________________________________________________________________________________________________________
          ___________________________________________________________________________________________________________
          
          
          
          
          CTD DATA CONSISTENCY CHECK
          
          The WHP-Exchange format bottle and/or CTD data from this cruise have been 
          examined by a computer application for contents and consistency. The parameters 
          found for the files are listed, a check is made to see if all CTD files for this 
          cruise contain the same CTD parameters, a check is made to see if there is a 
          one-to-one correspondence between bottle station numbers and CTD station 
          numbers, a check is made to see that pressures increase through each file for 
          each station, and a check is made to locate multiple casts for the same station 
          number in the bottle data. Results of those checks are reported in this 
          '_check.txt' file.
          
          When both bottle and CTD data are available, the CTD salinity data (and, if 
          available, CTD oxygen data) reported in the bottle data file are subtracted from 
          the corresponding bottle data and the differences are plotted for the entire 
          cruise. Those plots are not available for this cruise
          
          FOLLOWING PARAMETERS FOUND FOR BOTTLE FILE:
          			
                             EXPOCODE  DATE       CTDTMP   NITRAT
                             SECT_ID   TIME       CTDSAL   NITRIT
                             STNNBR    LATITUDE   SALNTY   PHSPHT
                             CASTNO    LONGITUDE  CTDOXY   CFC-11
                             SAMPNO    DEPTH      OXYGEN   CFC-11_FLAG_W
                             BTLNBR    CTDPRS     SILCAT   CFC-12
                                                           CFC-12_FLAG_W
          
           All ctd parameters match the parameters in the reference station.
           Station #1 exists in a16n_hy1.csv, but does not have a corresponding CTD file.
           No bottle pressure inversions found.
           Bottle file pressures are increasing.
           a16n_hy1.csv contains stations with multiple casts:

                             station 61:      2 casts.
                             station 62:      2 casts.
                             station 63:      2 casts.
                             station 65:      2 casts.

          
          ___________________________________________________________________________________________________________
          ___________________________________________________________________________________________________________
          
          
          

          DATA PROCESSING NOTES
          
          Date      Contact      Data Type        Data Status Summary
          --------  -----------  ---------------  --------------------------------------
          04/16/99  Jenkins      He/Tr            Projected Submission Date
                    1999.09.15 (disk crash/must reprocess)
                            
          06/16/99  Talley       DOC              Data Update; See note:
                    I don't see the file anywhere.  I had a subset of my 9-track tapes 
                    read off several years ago, but none of them have the A16 (MCTT) 
                    documentation and so I suspect it is on one of the existing 9-
                    tracks, which we no longer can read since there is no equipment 
                    here to do it.  so it will have to be typed or scanned in. Lynne
                            
          02/14/00  Huynh        DOC              Doc Update  pdf, txt versions online
                            
          03/13/00  Sandborn     BTL              Update Needed; See note:
                    Because of the problems that were found in the distribution of 
                    OCEANUS 202 on the WHPO site, I am proposing to send John 
                    Bullister the data transmittal file that ODF has in it's archives.  
                    I have reformatted the file to be similar to the WHP format.
                      Differences are:
                        CTDTMP ODF file is to 3 decimal places
                        THETA  ODF file is to 3 decimal places
                        SALNTY ODF file is to 3 decimal place
                        QUALTI ODF file has no coding
                    I believe my solution will assist John and not hold up his data 
                    submission.  I had reviewed the WHPO data file with ODF data file 
                    and was at a point that  I could easily have added the bottle 
                    numbers.  I opted not to do that because of the pressure 
                    differences.  If it is not a problem that the temperature and 
                    salinity are reported to thousandths and someone at WHPO must add 
                    the data coding, then all is good.  I tried to download the "raw" 
                    data files and create a WHP format report.  Unfortunately, some of 
                    the archive tapes were unreadable. 
                    
                    Listed below are problems that I found in the WHPO file.
                    1. The pressures in the WHPO file are off by ~5db at ~4000db.  The 
                       pressures are also reported to tenths, the current transmittal 
                       file reports the pressure to whole values.
                       >> I was able to cut and paste in the pressures to tenths from 
                          an ODF file.
                    2. Theta is calculated to 4 decimal places. ODF's current file is 
                       to 3 decimal places.
                    3. The oxygen and nutrients do not match ODF files. It appears 
                       that WHPO converted liter units to kilograms and this accounts for 
                       the difference.
                    4. There are added levels, one at the bottom evidently from the 
                       CTD data. Some stations have extra levels also appears to be from 
                       the CTD that are not in ODF's current data set. 
                       >>I was able to add these extra levels from an ODF file.
                    5. The WHPO file has lost part of Station 122 and all of Stations 
                       123-129. 
                       >> These are in the file sent to John.
                    6. It appears that the data on the WHPO was from an older 
                       distribution of the data. Fortunately, it appears that there were 
                       no major changes in the data that is archived by ODF other than 
                       the added levels. Unfortunately, the conversion from depth to 
                       pressure was done incorrectly and the conversion from liters to 
                       kilograms resulted in differences. This conversion resulted in 
                       data that was reasonable unlike pressure.
                            
          
          Date      Contact      Data Type        Data Status Summary
          --------  -----------  ---------------  --------------------------------------
          04/20/00  Bullister    CFCs             Submitted along with CFC DOC file
                            
          05/22/00  Huynh        DOC              CFC report added to pdf, txt docs
                            
          08/07/00  Bullister    CFCs             Data are Public    
                    I was the CFC PI on A16N and sent the data to the WHPO in April 2000.  
                    The data should have been made publicly available, but have not been 
                    so far. 
                            
          08/09/00  Bartolacci   CFCs             Data Reformatted; See note:
                    file submitted by K. Sanborn was edited to conform to WOCE format 
                    and had CFC columns added to the file by gen_dummy_cfc.pl to aid 
                    in merging incoming CFCs.  This edited file called a16nhy_new.txt.
                            
          08/10/00  Anderson     BTL              Website Updated; see merge notes:  
                     Merging process started jointly between DMB and SRA.  Merging 
                      completed by SRA.
                     A16Ncfc.dat - removed first four lines of data.  Edited file 
                      called A16Ncfc_edt.dat
                     A16Ncfc_edt.dat - Swapped columns 2 (samp) and 3 (cast) for mrgsea 
                      to merge data. Removed cast number "2" from sample numbers 
                      (e.g. sample #01 was called 201, not same nomenclature as hyd 
                      file) on stations 11, 61, 62, 63, 65 (all cast 2).
                    2000.10.14 SRA

                     a16nhy_rplcd_2000.08.15.txt - this is outdated working bottle 
                      data file. Moved original dir and replace with current bottle 
                      data file containing CFCs.
                    2000.08.15 SRA

                    *** Ran ~danie/tools/wocecvt on updated bottle file. (2000.08.15 SRA)
                    *** NOTE: SANBORN bottle data file and CFC data file both had data 
                              for station 11 cast 02, but WHOI .sum file only listed 
                              station 11 cast 01 (no cast 02).  Will leave as is and 
                              document.
                    2000.08.15 SRA
          
                    a16nhy_new.txt - new bottle file obtained from:    
                       ../original/FROM_STS_2000.03.13_SANBORN
                  
          08/15/00  Bartolacci   BTL/SUM          Cast discrepancy, station 11, See note:
                    Please note, cast discrepancy between sumfile and new odf bottle 
                    file for station 11. Sumfile has station 11, cast 1 while bottle 
                    file and CFC file has station 11 cast 2. All merging notes are in 
                    original subdirectory under 2000.04.20_A16N_CFC_BULLISTER
          
          08/15/00  Anfuso       CFCs             Website Updated  CFC 11 & 12 merged 
                    into new BTL file  Merged CFC11 and CFC12 into new ODF version of 
                    bottle file. Note: Quality flags are for CFC11 and CFC12.
                            
          
          Date      Contact      Data Type        Data Status Summary
          --------  -----------  ---------------  --------------------------------------
          11/03/00  Bartolacci   SUM              Website Updated  Reformatted SUM 
                    file online  The current online sumfile has been replaced with the 
                    newly reformatted sumfile, completed by 
                    S. Anderson on 2000.11.03. 
                    
                    The following changes were made as per the notes.a16n readme 
                    accompanying the file:
                     Reformatted to conform with the accepted WHPO format.
                     Latitude and longitude minutes were xx.x changed to xx.x0.
                     Station 11 - .sum had cast 1, .hyd had cast 2.  Changed .sum to 
                      cast 2 per data report (SIO ref. 91-16).
                    All references have been updated to reflect this change.
                            
          06/20/01  Uribe        BTL              Website Updated  
                    EXCHANGE File Added  Bottle file in exchange format has been linked to 
                    website.
                            
          06/21/01  Uribe        CTD/BTL          CTD EXCHANGE File Online, BTL modified 
                    BTL EXCHANGE file modified  The exchange bottle file name in directory 
                    and index file was modified to lower case.
                    CTD exchange files were put online.
                            
          08/27/01  Swift        He/Tr            Data Request  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.
                            
          12/20/01  Hajrasuliha  CTD              Internal DQE completed  See note:
                    Created *check.pl for this cruise. No *.ps files created for this 
                    cruise.
                    
          12/20/01  Uribe        CTD              Website Updated  EXCHANGE File Added
                    CTD has been converted to exchange using the new code and put 
                    online. Sumfile has a station 11 cast 2 and CTDs have a file for a 
                    station 11 cast 1 only. For this reason and for the purpose of the 
                    conversion, the 2 was made a 1 to allow for the code  to work.
                            
          08/27/03  Bullister    CTD/SUM/BTL/DOC  Permission given to post data on Web site
                    You have my permission to obtain the data from Frank and post them at 
                    the website. You should include the caveats that these data are the 
                    raw shipboard version, are still preliminary and will be updated. 
                                      
          08/29/03  Coartney     DOC              Website Updated  New text doc online
                            
          04/30/04  Kappa        DOC              PDF and TEXT Cruise Reports Updated
                     Added cruise summary pages
                     Added SIO-generated station plot
                     Added SIO-generated CTD Data Consistency Check
                     Added these Data Processing Notes to PDF and TEXT reports
                    
 
