A. Cruise Narrative A.1 Highlights A.1.a WOCE designation P17N A.1.b EXPOCODE 325021/1 A.1.c Chief Scientist David L. Musgrave University of Alaska Fairbanks, AK phone: 907-474-7837 fax: 907-474-7204 e-mail: musgave@ims.alaska.edu A.1.d Ship A.1.e Ports of call San Francisco, California-Sitka, Alaska (USA) A.1.f Cruise dates 15-May-1993 to 26-Jun-1993 A.2 Cruise Summary Information A.2.a Geographic boundaries 57N 158W 123W 38N A.2.b Stations occupied tations were numbered consecutively from the beginning of the cruise. * 202 CTD/36 bottle rosette stations, 47 with LADCP 1. 127 WOCE stations (1-99,121-148), 33 with LADCP 2. 21 coastal stations into Alaska Peninsula (100-120), 0 with LADCP 3. 39 Sitka Sound stations (149-187), 0 with LADCP 4. 16 Sitka Eddy stations (188-203), 14 with LADCP * 10 Large volume sampling (Gerard barrel) stations A.2.c Floats and drifters deployed A.2.d Moorings deployed or recovered A.3 List of Principal Investigators Table1: List of Principal Investigators Name Parameter Institution ------------------------------------------------------------- Rana Fine CFC RSMAS Teresa Chereskin ADCP, LADCP SIO Wilf Gardner Transmissometer TAMU Catherine Goyet Carbon Dioxide WHOI Charles Keeling Carbon Dioxide SIO Robert Key Large Volume Carbon-14 Princeton Radium-228 John Lupton Helium-3 NOAA/PMEL Dave Musgrave CTD-hydrography IMS-UAF Tom Royer CTD-hydrography IMS-UAF Paul Quay AMS Carbon-14 UW Jim Swift CTD-hydrography and SIO-ODF nutrients support Zafir Top Helium-3, Tritium RSMAS Rick Thomson Surface Drifters IOS/BC ------------------------------------------------------------ Disposition of data: please contact the individual investigators listed above. We are following the US WHP data policy, by which all preliminary results are immediately available to all US WOCE investigators funded for Pacific basin projects, with proprietary rights for two years for usage and publication of the data given to the individual investigator responsible for each particular measurement. Any use of publication of these data without permission from the principal investigator responsible for that measurement is in violation of this agreement. Collaborative work is encouraged. A.4 Scientific Programme and Methods The R/V Thompson departed San Francisco for cruise 21 (leg 01) on 15-May-1993. This was the first WOCE hydrographic cruise on the R/V Thompson. P17N was supported by the National Science Foundation's Ocean Science Division. The Ocean Data Facility of Scripps Institution of Oceanography (ODF/SIO) provided the basic technical support for this cruise. Because of their sea-going experience with the WOCE Hydrographic Program (WHP) and their prior support of JGOFS activities on the R/V Thompson, we had very few problems with equipment. The worst problem seemed to be occasional malfunctioning of the General Oceanics pylon. We had extremely good weather (for the Northeast Pacific) and were delayed only two times: due to weather for about 24 hours at station 72 and for about 8 hours at a non-WOCE station (194). We had three weather days planned and gained additional days due to a cruising speed of slightly greater than 10 knots. The additional days were spent on hydrographic work on the Alaska Peninsula shelf, in Sitka Sound and offshore of Sitka. All WOCE stations were to the bottom and included a rosette/CTD cast. Basic station spacing in the open ocean was 30 nm, with higher resolution in regions of steep topography (off Pt. Arena, California, over the Mendicino ``Ridge'', over the Aleutian Trench, and at the shelf break into Sitka). The Alaska Peninsula and Sitka Sound stations were to the bottom (generally less than 200 m) and the Sitka Eddy stations were to the bottom or 1000m or 2000 m. Sampling was done with a 36-place General Oceanics pylon on a rosette frame with 10-liter bottles and a CTD (SIO/ODF CTD \#1), transmissometer, altimeter, and pinger. The CTD data stream consisted of elapsed time, pressure, two temperature channels, conductivity, oxygen, altimeter and transmissometer signals. All WOCE profiles were full water column depth. Water samples were collected for analyses of salt, oxygen, silica, phosphate, nitrate, nitrite on all stations and of CFC-11, CFC-12, helium-3, helium-4, tritum, AMS C14, total CO2 and total alkalinity on selected stations. A Lowered Acoutic Doppler Current Profiler was mounted to the rosette frame which was specially made so that no bottles needed to be removed. The LADCP was mounted only for stations near steep bathymetry. It's pressure case was rated to 5500 dbar so at station 87 at the crossing of the deepest part of the Aleutian Trench (6000 m), the LADCP was dismounted and then remounted for a second cast. The time to mount or dismount the LADCP was about one-half hour since the rosette needed to be partially dismantled. Large volume sampling was made with 270 liter Gerard barrels for analyses of C14 Ra(228), salinity, oxygen, and nutrients on 10 stations. We had very good weather for all the Large Volume Stations and had no problems with pretrips (wire speeds of 30 meters/minute for downcasts). The time for the LVS's was greater than that alloted for in the cruise plan. However, the time gained by cruise speeds greater than 10 knots more than made up for the lost time on the LVS's. A.5 Major Problems and Goals not Achieved No major problems were encountered on the cruise. The wind speed and direction of the IMET system failed early in the cruise. The shipboard underway system did not log data until station 10 due to a software error. The GO pylon had major problems in firing bottles, however all misfirings were detectable and the console operator was able to compensate for the misfires. A.6 Other Incidents of Note A.7 List of Cruise Participants Table 2: List of Cruise Participants Name Instutition Responsibility ------------------------------------------------------------------------------ 1 Dave Musgrave UAF Chief Scientist 2 Tom Royer UAF Co-Chief Scientist 3 Robert T. Williams STS/ODF Data/Marine Tech, WLdr,Oxygen 4 Carl Mattson STS/ODF Electronics Specialist 5 Dave Muus STS/ODF Data/Marine Tech, WLdr 6 Dave Nelson STS/ODF/URI Marine Tech 7 Stacey Morgan STS/ODF Oxygen/Nutrients 8 Dennis Guffy STS/ODF/TAMU Nutrients 9 Laura Goepfert STS/ODF Marine Tech/Salt 10 Marie-Claude Beaupre STS/ODF Nutrients/Oxygen 11 Craig Hallman STS/ODF Marine Tech/Salt 12 Teri Chereskin SIO ADCP,LADCP 13 Rich Rotter Princeton Large Volume extractions 14 Georges Paradis PMEL Helium sampling 15 Chris Heuer RSMAS Helium/tritium sampling 16 Emma Bradshaw RSMAS CFC 17 Kevin Maillet RSMAS CFC 18 Maren Tracy WHOI CO2 19 Bob Adams WHOI CO2 20 Aaron Smith WHOI CO2 21 Rolf Sonnerup UW AMS 14C 22 Steve Sweet UAF Watch Stander 23 Heather Hunt UAF Watch Stander _____________________________________________________________________________ Table 3: Insitutuions ----------------------------------------------------------------------------- NOAA/PMEL NOAA Pacific Marine Environmental Laboratory 7600 Sand Point Way NE Seattle, WA 98115-0700 SIO Scripps Institution of Oceanography University of California of San Diego 9500 Gilman Drive La Jolla, CA 92093 TAMU Texas A&M University Department of Oceanography College Station, TX 77843 WHOI Woods Hole Oceanographic Institute Woods Hole, Ma 02543 Princeton Princeton University Princeton, NJ 08540 RSMAS Rosential School of Marine and Atmospheric Science Miami, FL UAF University of Alaska Fairbanks, AK UW University of Washington School of Oceanography Seattle, WA 98195 ----------------------------------------------------------------------------- B. Underway Measurements B.1 Navigation and bathymetry Navigation data and underway bathymetry was acquired from the ship's Bathy 2000 system via RS-232. It was logged automatically at one-minute intervals by one of the Sun Sparcstations to provide a time-series of underway position, course, speed and bathymetry data. These data were used for all station positions, PDR depths, and for bathymetry on vertical sections. B.2 Acoustic Doppler Current Profiler (ADCP) An ADCP was run while underway. B.3 Thermosalinograph and underway dissolved oxygen, etc pCO was collected while underway. B.4 XBT and XCTD B.5 Meteorological observations Thompson's IMET system collected (surface water temperature and conductivity, meterological parameters, GPS navigation, ship's speed and heading) and bathymetry from the shipboard PDR. The IMET's wind speed and direction sensor malfunctioned early in the cruise. B.6 Atmospheric chemistry C. Hydrographic Measurements C.1. Description of Measurement Techniques and Calibration Basic Hydrography Program The basic hydrography program consisted of salinity, dissolved oxygen and nutrient (nitrite, nitrate, phosphate and silicate) measurements made from bottles taken on CTD/rosette casts plus pressure, temperature, salinity and dissolved oxygen from CTD profiles. 202 CTD/Rosette casts were made, usually to within 10 meters of the bottom. Of these 202 casts, there were a total of 128 WOCE casts. 10 Large Volume stations were occupied with two casts per station. On the WOCE stations, 4343 bottles were tripped resulting in 4319 usable bottles. No major problems were encountered during any phase of the operation. The resulting data set met and in many cases exceeded WHP specifications. C.1.a. Water Sampling Package Hydrographic (rosette) casts were performed with a new design of the rosette system consisting of a 36-bottle ODF-designed rosette frame, a 36-place pylon (General Oceanics 1016) and 36 10-liter Bullister-style PVC bottles. The frame worked well and held the Lowered Acoustic Doppler Current Profiler (LADCP) without sacrificing any of the 36 samplers. The G.O. pylon had operating problems which could usually be overcome by the operator through the diagnostics routine. The Bullister-style samplers worked well, but had fragile end-cap edges and tight valves. Recommendations for modifications were made and have since been implemented. Underwater electronic components consisted of an ODF-modified NBIS Mark III CTD (ODF #1) and associated sensors, SeaTech transmissometer provided by Texas A&M University (TAMU), RDI LADCP, Benthos altimeter and Benthos pinger. The CTD was mounted horizontally along the bottom of the rosette frame, with the transmissometer, dissolved oxygen and secondary PRT sensors deployed alongside. The LADCP was mounted vertically in the frame inside the bottle rings. The Benthos altimeter provided distance-above- bottom in the CTD data stream. The Benthos pinger was monitored during a cast with a precision depth recorder (PDR) in the ship's laboratory. The rosette system was suspended from a three-conductor electro-mechanical (EM) cable. Power to the CTD and pylon was provided through the cable from the ship. Separate conductors were used for the CTD and pylon signals. Each rosette cast was performed to within 10 meters of the bottom, unless the bottom returns from both the pinger and altimeter were extremely poor. Bottles on the rosette were each identified with a unique serial number. Usually these numbers corresponded to the reverse of the pylon tripping sequence, 1-36, with the first bottle tripped being bottle #36 (deepest bottle). Bottle replacements were necessary, and the replacement bottles were numbered 37 and 38. Averages of CTD data corresponding to the time of bottle closure were associated with the bottle data during a cast. Pressure, depth, temperature, salinity, density and nominally-corrected oxygen were immediately available to facilitate examination and quality control of the bottle data as the sampling and laboratory analyses progressed. The deck watch prepared the rosette approximately 45 minutes prior to a cast. All valves, vents and lanyards were checked for proper orientation. The bottles were cocked and all hardware and connections rechecked. Upon arrival on station, time, position and bottom depth were logged and the deployment begun. The rosette was moved into position under a projecting boom from the rosette room using an air-powered cart on tracks. Two stabilizing tag lines were threaded through rings on the frame. CTD sensor covers were removed and the pinger turned on. Once the CTD acquisition and control system in the ship's laboratory had been initiated by the console operator and the CTD and pylon had passed their diagnostics, the winch operator raised the package and extended the boom over the side of the ship. The package was then quickly lowered into the water, the tag lines removed and the console operator notified by radio that the rosette was at the surface. Recovering the package at the end of deployment was essentially the reverse of the launching. Two tag lines connected to air tuggers and terminating in large snap hooks were manipulated on long poles by the deck watch to snag recovery rings on the rosette frame. The package was then lifted out of the water under tension from the tag lines, the boom retracted, and the rosette lowered onto the cart. Sensor covers were replaced, the pinger turned off and the cart with the rosette moved into the rosette room for sampling. A detailed examination of the bottles and rosette would occur before samples were taken, and any extraordinary situations or circumstances were noted on the sample log for the cast. Rosette maintenance was performed on a regular basis. O-rings were changed as necessary and bottle maintenance performed each day to insure proper closure and sealing. Valves were inspected for leaks and repaired or replaced. Large Volume Sampling (LVS), see Key et. al (1991) was also performed on this expedition. These casts were carried out with ~270-liter stainless steel Gerard barrels on which were mounted 5-liter bottles with deep-sea reversing thermometers (DSRTs). Samples for salinity, silicate and 14C were obtained from the Gerard barrels; samples for salinity and silicate were drawn from piggyback Niskin-style bottles. The salinity and silicate samples from each piggyback bottle were used for comparison with the Gerard barrel salinity and silicate to verify the integrity of the Gerard sample. C.1.b. Underwater Electronics Packages CTD data were collected with a modified NBIS Mark III CTD (ODF CTD #1). This instrument provided pressure, temperature, conductivity and dissolved O2 channels, and additionally measured a second temperature (FSI temperature sensor) as a calibration check. Other data channels included elapsed-time, an altimeter, several power supply voltages and a transmissometer. The instrument supplied a standard 15-byte NBIS-format data stream at a data rate of 25 fps. Modifications to the instrument included a revised dissolved O2 sensor mounting; ODF-designed sensor interfaces for the FSI PRT and the SeaTech transmissometer; implementation of 8-bit and 16-bit multiplexer channels; an elapsed-time channel; instrument id in the polarity byte and power supply voltages channels. The O2 sensor was deployed in an ODF-designed pressure-compensated holder assembly mounted separately on the rosette frame and connected to the CTD by an underwater cable. The transmissometer interface was designed and built by ODF using an off-the-shelf 12-bit A/D converter. Although the secondary temperature sensor was located within 1 meter of the CTD conductivity sensor, it was not sufficiently close to calculate coherent salinities. It was used as a secondary temperature calibration reference rather than as a redundant sensor, with the intent of eliminating the use of mercury or electronic DSRTs as calibration checks. Standard CTD maintenance procedures included soaking the conductivity sensor in deionized water and placing a cap on the O2 sensor between casts to maintain sensor stability, and protecting the CTD from exposure to direct sunlight or wind to maintain an equilibrated internal temperature. The General Oceanics 1016 36-place pylon was used in conjunction with the General Oceanics pylon deck unit. There were numerous tripping problems caused by the G.O. pylon/deck unit combination. Usually these could be resolved by the console operator via the pylon diagnostics routine. The pylon emitted a confirmation message containing its current notion of bottle trip position, which was an aid in sorting out mis-trips. A further consequence of Using the G.O. pylon and deck unit also contributed to the magnitude of the variance of salinity differences. The pylon would take a variable amount of time to trip a bottle after the trip had been initiated. The time varied from 5 seconds to over 30 seconds. The acquisition software began averaging data corresponding to the rosette trip as soon as the trip was initiated, ending when the trip confirmed. Consequently, CTD rosette trip data used for the differences contained variable-length averages. C.1.c. CTD Data Acquisition, Processing and Control System The CTD data acquisition, processing and control system consisted of a Sun SPARC station 2 computer workstation, ODF-built CTD deck unit, General Oceanics pylon deck unit, CTD and pylon power supplies, and a VCR recorder for real-time analog backup recording of the sea-cable signal. The Sun system consisted of a color display with trackball and keyboard (the CTD console), 18 RS-232 ports, 2.5 GB disk and 8 mm cartridge tape. One other Sun SPARCstation 2 system was networked to the data acquisition system, as well as to the rest of the networked computers aboard the Thompson. These systems were available for real-time CTD data display as well as for providing hydrographic data management and backup. Each Sun SPARCstation was equipped with a printer and an 8-color drum plotter. The CTD FSK signal was demodulated and converted to a 9600 baud RS-232C binary data stream by the CTD deck unit. This data stream was fed to the Sun SPARCstation. The pylon deck unit was connected to the data acquisition system through a serial port, allowing the data acquisition system to initiate and confirm bottle trips. A bitmapped color display provided interactive graphical display and control of the CTD rosette sampling system, including real-time raw and processed data, navigation, winch and rosette trip displays. The CTD data acquisition, processing and control system was prepared by the console watch a few minutes before each deployment. A console operations log was maintained for each deployment, containing a record of every attempt to trip a bottle as well as any pertinent comments. Most CTD console control functions, including starting the data acquisition, were performed by pointing and clicking a trackball cursor on the display at icons representing functions to perform. The system then presented the operator with short dialog prompts with automatically-generated choices that could either be accepted as default or overridden. The operator was instructed to turn on the CTD and pylon power supplies, then to examine a real-time CTD data display on the screen for stable voltages from the underwater unit. Once this was accomplished, the data acquisition and processing was begun and a time and position automatically associated with the beginning of the cast. A backup analog recording of the CTD signal was made on a VCR tape, which was started at the same time as the data acquisition. A rosette trip display and pylon control window then popped up, giving visual confirmation that the pylon was initializing properly. Various plots and displays were initiated. When all was ready, the console operator informed the deck watch by radio. Once the deck watch had deployed the rosette and informed the console operator that the rosette was at the surface (also confirmed by the computer displays), the console operator provided the winch operator with a target depth (wire-out) and lowering rate (normally 60 meters/minute for this package). The package would then begin its descent. The console operator examined the processed CTD data during descent via interactive plot windows on the display, which could also be run at other workstations on the network. Additionally, the operator decided where to trip bottles on the up-cast, noting this on the console log. The PDR was monitored to insure the bottom depth was known at all times. The watch leader assisted the console operator when the package was ~400 meters above the bottom, and verify the range to the bottom using the distance between the bottom reflection and pinger signal displayed on the PDR. Between 300 to 60 meters above the bottom, depending on bottom conditions, the altimeter typically began signaling a bottom return on the console. The winch and altimeter displays allowed the watch leader to refine the target depth relayed to the winch operator and safely approach to within 10 meters of the bottom. Bottles were tripped by pointing the console trackball cursor at a graphic firing control and clicking a button. The data acquisition system responded with the CTD rosette trip data and a pylon confirmation message in a window. All tripping attempts were noted on the console log. The console operator then directed the winch operator to the next bottle stop. The console operator was also responsible for generating the sample log for the cast. After the last bottle was tripped, the console operator directed the deck watch to bring the rosette on deck. Once on deck, the console operator terminated the data acquisition and turned off the CTD, pylon and VCR recording. The VCR tape was filed. Usually the console operator also brought the sample log to the rosette room and served as the sample cop. C.1.d. CTD Laboratory Calibration Procedures Pre-cruise laboratory calibrations of the CTD pressure and temperature sensors were used to generate tables of corrections applied by the CTD data acquisition and processing software at sea. These laboratory calibrations were also performed post-cruise. Pressure and temperature calibrations were performed on CTD #1 at the ODF Calibration Facility (La Jolla). The pre-cruise calibration was done in May 1993 before the start of the expediton, and the post-cruise calibration was done in October 1993. The CTD pressure transducer was calibrated in a temperature-controlled water bath to a Ruska Model 2400 Piston Gauge pressure reference. Calibration curves were measured at 0.01, 11.74 and 31.22 deg.C to 2 maximum loading pressures (2775 and 6080 db) pre-cruise, and at 1.62 and 32.13 deg.C to 2 maximum loading pressures (1400 and 6080 db) post-cruise. Additionally, dynamic thermal-response step tests were conducted on the pressure transducer to calibrate dynamic thermal effects. CTD PRT temperatures were calibrated to an NBIS ATB-1250 resistance bridge and Rosemount standard PRT in a temperature-controlled bath. The primary CTD temperature was offset by ~1.5 deg.C to avoid the 0-point discontinuity inherent in the internal digitizing circuitry. Figures 1.5.3-1.5.4 summarize the laboratory calibrations performed on the primary PRT. These laboratory temperature calibrations are referenced to the ITS-90 standard. Calibration coefficients were converted to the IPTS-68 standard because calculated parameters, including salinity and density, are currently defined in terms of that standard. C.1.e. CTD Calibration Procedures This cruise was the first of 2 consecutive Pacific Ocean cruises for this CTD. Transfer standards and redundant sensors were used as calibration checks while at sea. An FSI secondary pressure reference was used as a pressure calibration transfer standard. An FSI PRT sensor was deployed as a second temperature channel and compared with the primary PRT channel on most casts. The secondary PRT sensor did not exhibit any appreciable drift during these expeditions. There was a constant offset maintained between the 2 PRTs throughout this leg. The response times of the sensors were first matched, then the temperatures compared for a series of standard depths from each CTD down-cast. CTD conductivity and dissolved O2 were calibrated to in-situ check samples collected during each rosette cast. Based on the stability of the conductivity calibration, there were no significant shifts in the CTD pressure or temperature. CTD Pressure and Temperature The final pressure and temperature calibrations were determined during post-cruise processing. Over 6000 db, there was a 1.5 db slope change between the pre- and post-cruise cold "deep" pressure laboratory calibrations, as well as an ~1.5 db offset between the 2 sets of pressure calibrations (pre- and post). After analyzing these 2 sets of calibrations, a decision was made to generate new tables of corrections based on averaging the data from both sets of pressure calibrations. These new corrections, generated by this new averaged calibration, were then reapplied to the data set for the cruise. Another reason to reapply the corrections to the block-averaged data was because the pressure model used had been further refined to more accurately apply the thermal shock correction. The primary temperature sensor (Rosemount Model 171BJ Serial No. 14304) laboratory calibration shows essentially the same curve pre- and post- cruise, with at most a .0004 deg.C shift in the range of 10-27 deg.C; colder and warmer than that range, the curves are essentially identical. It was therefore decided to stay with the pre-cruise PRT #1 correction for this data set. The secondary temperature sensor (FSI Model OTM-D212 Serial No. 1320) laboratory calibrations pre- and post-cruise showed some differences, but the same temperature ranges were not measured and these FSI sensors show a greater amount of variability. There did not appear to be any major shift, perhaps an ~1 millidegree shift in the range of 1-20 deg.C. Conductivity The CTD rosette trip pressure and temperature were used with the bottle salinity to calculate a bottle conductivity. Differences between the bottle and CTD conductivities were then used to derive a conductivity correction as a linear function of conductivity. Cast-by-cast comparisons had shown only minor conductivity sensor offset shifts, and no sensor slope changes. Conductivity differences were fit to CTD conductivity for all casts to determine the mean conductivity slope. The mean conductivity slope (-0.000523123 mmhos/cm) was used for all casts. Residual CTD #1 conductivity offset values were calculated after applying the conductivity slopes. The conductivity offsets were determined for each cast from the deepest bottle conductivities and then fit as a function of station number by groups. Smoothed offsets were applied to CTD conductivities in 5 station groups: 001-056, 057-067, 068-097, 098-189 and 190-202. The conductivity sensor was cleaned after stations 056 and 067. Stations 098-120 were shallow (maxp less than 600 db) and stations 146-189 were also shallow (mostly less than 200 db) so the smoothed conductivity offset determined from the deep group of stations 122-145 was applied to all these shallow casts. The group of stations 190-202 were mid-range, varying between 1010 and 2700 db. The CTD conductivity calibration represents a best estimate of the conductivity field throughout the water column. Note that the CTD calibration was not fit from the bottle conductivities cast-by-cast. Also, Some offsets were manually re-adjusted to account for discontinuous shifts in the conductivity transducer response, or to insure a consistent deep T-S relationship from station to station. The conductivity cell on this CTD proved extremely stable as demonstrated by the constant calibration slope and offsets that could easily be fit by station groups. The limit of repeatability for all salinites is +/-0.004PSU and +/-0.001 PSU for deep salinities represents the limit of repeatability of the bottle salinities (Autosal, rosette, operators and samplers). This limit agrees with station overlays of deep T-S. Within a cast (a single salinometer run), the precision of bottle salinities appears to exceed 0.001 PSU. The precision of the CTD salinities appears to exceed 0.0005 PSU. CTD Dissolved Oxygen There are a number of problems with the response characteristics of the Sensormedics O2 sensor used in the NBIS Mark III CTD, the major ones being a secondary thermal response and a sensitivity to profiling velocity. Because of these problems, CTD rosette trip data cannot be directly calibrated to O2 check samples. Instead, down-cast CTD O2 data are derived by matching the up-cast rosette trips along isopycnal surfaces. The differences between CTD O2 data modeled from these derived values and check samples are then minimized using a non-linear least-squares fitting procedure. The mean of the differences is not zero, because the O2 values are weighted by pressure before fitting. The standard deviations of 0.05 ml/l for all oxygens and 0.03 ml/l for deep oxygens are only intended as metrics of the goodness of the fits. ODF makes no claims regarding the precision or accuracy of CTD dissolved O2 data. The general form of the ODF O2 conversion equation follows Brown and Morrison (1978) and Millard (1982), Owen (1985). ODF does not use a digitized O2 sensor temperature to model the secondary thermal response but instead models membrane and sensor temperatures by low-pass filtering the PRT temperature. In-situ pressure and temperature are filtered to match the sensor response. Time-constants for the pressure response p, and two temperature responses Ts and Tf are fitting parameters. The sensor current, or Oc, gradient is approximated by low-pass filtering 1st-order Oc differences. This term attempts to correct for reduction of species other than O2 at the cathode. The time-constant for this filter, og, is a fitting parameter. Oxygen partial-pressure is then calculated: Opp=[c1Oc+c2]fsat(S,T,P)e(c3Pl+c4Tf+c5Ts+c6___) where: Opp = Dissolved O2 partial-pressure in atmospheres (atm); Oc = Sensor current (amps); fsat(S,T,P) = O2 saturation partial-pressure at S,T,P (atm); S = Salinity at O2 response-time (PSUs); T = Temperature at O2 response-time (deg.C); P = Pressure at O2 response-time (decibars); Pl = Low-pass filtered pressure (decibars); Tf = Fast low-pass filtered temperature (deg.C); Ts = Slow low-pass filtered temperature (deg.C); ___ = Sensor current gradient (amps/secs). C.1.f. CTD Data Processing ODF CTD processing software consists of over 30 programs running under the Unix operating system. The initial CTD processing program (ctdba) is used either in real-time or with existing raw data sets to: o Convert raw CTD scans into scaled engineering units, and assign the data to logical channels; o Filter specific channels according to specified filtering criteria; o Apply sensor or instrument-specific response-correction models; o Provide periodic averages of the channels corresponding to the output time-series interval; and o Store the output time-series in a CTD-independent format. Once the CTD data are reduced to a standard-format time-series, they can be manipulated in a number of various ways. Channels can be additionally filtered. The time-series can be split up into shorter time-series or pasted together to form longer time-series. A time-series can be transformed into a pressure-series, or a different interval time-series. For temperature, conductivity and oxygen, calibration corrections to the series are maintained in separate files and are applied whenever the data are accessed. The pressure calibration corrections are applied during reduction of the data to time-series. ODF data acquisition software acquired and processed the CTD data in real- time, providing calibrated, processed data for interactive plotting and reporting during a cast. The 25 hz data from the CTD were filtered, response-corrected and averaged to a 2 hz (0.5 seconds) time-series. Sensor correction and calibration models were applied to pressure, temperature, conductivity and O2. Rosette trip data were extracted from this time-series in response to trip initiation and confirmation signals. The calibrated 2 hz time-series data were stored on disk (as were the 25 hz raw data) and were available in real-time for reporting and graphical display. At the end of the cast, various consistency and calibration checks were performed, and a 2.0 db pressure-series of the down-cast was generated and subsequently used for reports and plots. CTD plots generated automatically at the completion of deployment were checked daily for potential problems. The two PRT temperature sensors were inter-calibrated and checked for sensor drift. The CTD conductivity sensor was monitored by comparing CTD values to check-sample conductivities and by deep T-S comparisons with adjacent stations. The CTD dissolved O2 sensor was calibrated to check-sample data. A few casts exhibited conductivity offsets due to biological or particulate artifacts. Sometimes casts are subject to noise in 1 or more channels. In these cases the 2 hz time-series were additionally filtered, using a spike- removal filter that replaced points exceeding a specified multiple of the standard deviation least-squares polynomial fit of specified order of segments of the data. The filtered points were replaced by the filtering polynomial value. Density inversions can appear in high-gradient regions. Detailed examination of the raw data shows significant mixing occurring in these areas because of ship roll. In order to minimize these inversions, a ship- roll filter was applied to most casts during pressure-sequencing to disallow pressure reversals. Pressure intervals with no time-series data can optionally be filled by double-parabolic interpolation. When the down-cast CTD data have excessive noise, gaps or offsets, the up- cast data are used instead. CTD data from down- and up-casts are not mixed together in the pressure-series data because they do not represent identical water columns (due to ship movement, wire angles, etc.). Table 4 provides a list of CTD casts requiring special attention. +------------------------------------------------------------------------------------------+ Cast Problem/Comment Solution | +-----+-------------------------------------------------+----------------------------------+ 007/01CTD O2 offset 2993 db offset. | 011/01Salt offset 650-658 db offset. | 022/01Retermination after cast | | 024/01Power outage down-cast filtered-CTD O2 questionable 4902| | | db to bottom. | 027/01Power outage down-cast filtered-CTD O2 questionable 5214| | | db to bottom. | 042/012.9 min pause @ 3098 db-possible feature there inno action. | | both dn/up & all parameters | | 044/01Salt offset 3070-3186 db offset. | 047/01Salt offset 1852-4046 db offset. | 057/01Cond cell cleaned after cast; shift in cond offset| | 059/01Salt offset 1918-1945 db offset. | 060/01CTD O2 feature ~3500 db both dn/up no action. | 066/01No surface bottle O2 no action. | 068/01Cond cell cleaned after cast; shift in cond offset| | 070/01Salt offset 1525-1588 db/power outage down-cast offset/filtered & offset. | 073/01CTD O2 bad top 130 db; retermination after cast no action. | 080/01Numerous salt offsets due to biological matter filtered/chopped off bottom 112 db.| 087/02Salt offset 1670-2008 db/no discrete O2 offset/used CTD O2 fit from 087/01.| 091/011.8 min pause @ 3980 db no action-CTD O2 questionable| | | 3978-3988 db. | 092/010.46 min pause @ 3570 db no action-CTD O2 questionable| | | 3568-3584 db. | 093/01CTD O2 feature ~2800 db both dn/up no action. | 120/01CTD hit bottom; no apparent cond sensor shift | | 123/01Salt offset 1206-1366 db offset. | 188/01Cast maxp < 200 db - CTD O2 bad top 40 db no action. | 190/02Numerous down-cast cond drop-outs up-cast used. | 195/01Impossible to get CTD O2 to fit blanked out CTD O2 data. | 196/01Salt offset 38-46 db filtered. | +-----+-------------------------------------------------+----------------------------------+ Table 4 Tabulation of atypical CTD casts. C.1.g. Bottle Sampling At the end of each rosette deployment water samples were drawn from the bottles in the following order: o CFCs; o Helium; o Oxygen; o Total CO2; o Alkalinity; o AMS C14; o Tritium; o Nutrients; o Salinity. The correspondence between individual sample containers and the rosette bottle from which the sample was drawn was recorded on the sample log for the cast. This log also included any comments or anomalous conditions note about the rosette and bottles. One member of the sampling team was designated the sample cop, whose sole responsibility was to maintain this log and insure that sampling progressed in proper drawing order. Normal sampling practice included opening the drain valve before opening the air vent on the bottle, indicating an air leak if water escaped. This observation together with other diagnostic comments (e.g., "lanyard caught in lid", "valve left open") that might later prove useful in determining sample integrity were routinely noted on the sample log. Drawing oxygen samples also involved taking the sample draw temperature from the bottle. The temperature was noted on the sample log and was sometimes useful in determining leaking or mis-tripped bottles. Once individual samples had been drawn and properly prepared, they were distributed to their respective laboratories for analysis. Oxygen, nutrients and salinity analyses were performed on computer-assisted (PC) analytical equipment networked to Sun SPARCStations for centralized data analysis. The analyst for a specific property was responsible for insuring that their results updated the cruise database. C.1.h. Bottle Data Processing The first stage of bottle data processing consisted of verifying and validating individual samples, and checking the sample log (the sample inventory) for consistency. At this stage, bottle tripping problems were usually resolved, sometimes resulting in changes to the pressure, temperature and other CTD properties associated with the bottle. Note that the rosette bottle number was the primary identification for all samples taken from the bottle, as well as for the CTD data associated with the bottle. All CTD trips were retained (whether confirmed or not), so resolving bottle tripping problems simply consisted of assigning the right rosette bottle number to the right CTD trip level. Diagnostic comments from the sample log were then translated into preliminary WOCE quality codes, together with appropriate comments. Each code indicating a potential problem was investigated. The second stage of processing began once all the samples for a cast had been accounted for. All samples for bottles suspected of leaking were checked to see if the property was consistent with the profile for the cast, with adjacent stations, and where applicable, with the CTD data. All comments from the analysts were examined and turned into appropriate WHP water sample codes. Oxygen flask numbers were verified, as each flask is individually calibrated and significantly affects the calculated O2 concentration. The third stage of processing continued throughout the cruise and until the data set is considered "final". Various property-property plots and vertical sections were examined for both consistency within a cast and consistency with adjacent stations. In conjunction with this process the analysts would review and sometimes revise their data as additional calibration or diagnostic results became available. Assignment of a WHP water sample code to an anomalous sample value was typically achieved through consensus, usually also involving one of the chief scientists. WHP water bottle quality flags were assigned with the following additional interpretations: | 3 | An air leak large enough to produce an observable | effect on a sample is identified by a code of 3 on the | bottle and a code of 4 on the oxygen. (Small air | leaks may have no observable effect, or may only | affect gas samples.) 4 | Bottles tripped at other than the intended depth were | assigned a code of 4. There may be no problems with | the associated water sample data. WHP water sample quality flags were assigned using the following criteria: | 1 | The sample for this measurement was drawn from a | bottle, but the results of the analysis were not (yet) | received. 2 | Acceptable measurement. 3 | Questionable measurement. The data did not fit the | station profile or adjacent station comparisons (or | possibly CTD data comparisons). No notes from the | analyst indicated a problem. The data could be | correct, but are open to interpretation. 4 | Bad measurement. Does not fit the station profile, | adjacent stations or CTD data. There were analytical | notes indicating a problem, but data values were | reported. Sampling and analytical errors were also | coded as 4. 5 | Not reported. There should always be a reason | associated with a code of 5, usually that the sample | was lost, contaminated or rendered unusable. 9 | The sample for this measurement was not drawn. WHP water sample quality flags were assigned to the CTDSAL (CTD salinity) parameter as follows: | 2 | Acceptable measurement. 3 | Questionable measurement. The data did not fit the | bottle data, or there was a CTD conductivity | calibration shift during the cast. 4 | Bad measurement. The CTD data were determined to be | unusable for calculating a salinity. 8 | The CTD salinity was derived from the CTD down cast, | matched on an isopycnal surface. WHP water sample quality flags were assigned to the CTDOXY (CTD oxygen) parameter as follows: | 2 | Acceptable measurement. 4 | Bad measurement. The CTD data were determined to be | unusable for calculating a dissolved oxygen | concentration. 5 | Not reported. The CTD data could not be reported. 9 | Not sampled. No operational dissolved oxygen sensor | was present on this cast. Note that all CTDOXY values were derived from the down cast data, matched to the upcast along isopycnal surfaces. If the CTD salinity was footnoted as bad or questionable, the CTD oxygen is blank. Table 5 and 6 shows the number of samples drawn and the number of times each WHP sample quality flag was assigned for each basic hydrographic property: +-------------------------------------------------------------------------+ | Rosette Samples Stations 1-99, 121-148 | +-------------------------------------------------------------------------+ | Reported WHP Quality Codes | | levels 1 2 3 4 5 9 | +------------+-------------+----------------------------------------------+ | Bottle | 4343 | 0 4090 14 228 0 11 | | CTD Salt | 4343 | 0 4258 0 85 0 0 | | CTD Oxy | 4260 | 0 4227 33 0 0 83 | | Salinity | 4324 | 0 4264 12 48 6 13 | | Oxygen | 4292 | 0 4272 1 19 4 47 | | Silicate | 4293 | 0 4238 40 15 0 50 | | Nitrate | 4293 | 0 4272 6 15 0 50 | | Nitrite | 4006 | 0 3992 0 14 287 50 | | Phosphate | 4293 | 0 4201 5 87 0 50 | +------------+-------------+----------------------------------------------+ Table 5 Frequency of WHP quality flag assignments. +-------------------------------------------------------------------------+ | Large Volume Samples Stations 10,28,39,48,58,68,78,86,132,141 | +-------------------------------------------------------------------------+ | Reported WHP Quality Codes | | levels 1 2 3 4 5 6 7 8 9 | +--------------+-----------+----------------------------------------------+ |Bottle | 360 | 0 353 5 0 0 0 0 0 2 | |Salinity | 358 | 0 345 12 1 0 0 0 0 2 | |Silicate | 358 | 0 320 37 1 0 0 0 0 2 | |Nitrate | 358 | 0 0 0 358 0 0 0 0 2 | |Nitrite | 322 | 0 0 0 322 36 0 0 0 2 | |Phophate | 358 | 0 0 0 358 0 0 0 0 2 | |Pressure | 360 | 0 360 0 0 0 0 0 0 0 | |Temperature | 352 | 0 348 4 0 8 0 0 0 0 | +--------------+-----------+----------------------------------------------+ Table 6 Frequency of WHP LVS quality flag assignments. C.1.i. Pressure and Temperatures All pressures and temperatures for the bottle data tabulations on the rosette casts were obtained by averaging CTD data for a brief interval at the time the bottle was closed on the rosette, then correcting the data based on CTD laboratory calibrations. LVS pressures and temperatures were calculated from deep-sea reversing thermometer (DSRT) readings. Each DSRT rack normally held 2 protected (temperature) thermometers and 1 unprotected (pressure) thermometer. Thermometers were read by two people, each attempting to read a precision equal to one tenth of the thermometer etching interval. Thus, a thermometer etched at 0.05 degree intervals would be read to the nearest 0.005 degrees. Each temperature value reported on the LVS cast is therefore calculated from the average of four readings, provided both protected thermometers function normally. The pressure is verified by comparison with the calculation of pressure determined by wireout. The pressure from the thermometer is fitted by a polynomial equation which incorporates the wireout and wire angle. Calibration of the thermometers are performed in ODF's calibration facility depending on the age of the thermometer and within two years of the expedition. The temperatures are based on the International Temperature Scale of 1990. C.1.j. Salinity Analysis Salinity samples were drawn into 200 ml Kimax high alumina borosilicate bottles after 3 rinses, and were sealed with custom-made plastic insert thimbles and Nalgene screw caps. This assembly provides very low container dissolution and sample evaporation. As loose inserts were found, they were replaced to ensure a continued airtight seal. Salinity was determined after a box of samples had equilibrated to laboratory temperature, usually within 8-12 hours of collection. The draw time and equilibration time, as well as per-sample analysis time and temperature were logged. Two Guildline Autosal Model 8400A salinometers (55-654 and 57-396) were used to measure salinities. These were located in a temperature-controlled laboratory. The salinometers were modified by ODF and contained interfaces for computer-aided measurement. A computer (PC) prompted the analyst for control functions (changing sample, flushing) while it made continuous measurements and logged results. The salinometer cell was flushed until successive readings met software criteria for consistency, then two successive measurements were made and averaged for a final result. The salinometer was standardized for each cast with IAPSO Standard Seawater (SSW) Batch P-122, using at least one fresh vial per cast. The estimated accuracy of bottle salinities run at sea is usually better than 0.002 PSU relative to the particular Standard Seawater batch used. PSS-78 salinity , UNESCO 81, was then calculated for each sample from the measured conductivity ratios, and the results merged with the cruise database. Salinometer 55-654 was used on stations 001, 002 and 013-202. Salinometer 57-396 was used on stations 003-012. 4324 salinity measurements were made from the rosette stations; 358 measurements were made from the large volume stations. 376 vials of standard water were used. The temperature stability of the laboratory used to make the measurements was acceptable (usually within 4 deg.C of the salinometer bath temperature). There were no substantial problems noted with the analyses. The salinities were used to calibrate the CTD conductivity sensor. C.1.k. Oxygen Analysis Samples were collected for dissolved oxygen analyses soon after the rosette sampler was brought on board and after CFC and helium were drawn. Nominal 125 ml volume-calibrated iodine flasks were rinsed twice with minimal agitation, then filled via a drawing tube, and allowed to overflow for at least 3 flask volumes. The sample temperature was measured with a small platinum resistance thermometer embedded in the drawing tube. Draw temperatures were very useful in detecting possible bad trips even as samples were being drawn. Reagents were added to fix the oxygen before stoppering. The flasks were shaken twice to assure thorough dispersion of the MnO(OH)2 precipitate. They were shaken once immediately after drawing, and then again after 20 minutes. The samples were analyzed within 4-36 hours of collection. Dissolved oxygen analyses were performed with an SIO-designed automated oxygen titrator using photometric end-point detection based on the absorption of 365 nm wavelength ultra-violet light. Thiosulfate was dispensed by a Dosimat 665 buret driver fitted with a 1.0 ml buret. ODF uses a whole-bottle modified-Winkler titration following the technique of Carpenter (1965) with modifications by Culberson et. al (1991), but with higher concentrations of potassium iodate standard (approximately 0.012N) and thiosulfate solution (50 gm/l). Standard solutions prepared from pre-weighed potassium iodate crystals were run at the beginning of each session of analyses, which typically included from 1 to 3 stations. Several standards were made up during the cruise and compared to assure that the results were reproducible, and to preclude the possibility of a weighing error. Reagent/distilled water blanks were determined to account for oxidizing or reducing materials in the reagents. The auto-titrator generally performed very well. The samples were titrated and the data logged by the PC control software. The data were then used to update the cruise database on the Sun SPARCstations. Thiosulfate normalities and blanks, calculated from each standardization and corrected to 20 deg.C, were plotted versus time and were reviewed for possible problems. New thiosulfate normalities were recalculated after the blanks had been smoothed. These normalities were then smoothed, and the oxygen data were recalculated. Oxygens were converted from milliliters per liter to micromoles per kilogram using the in-situ temperature. Ideally, for whole-bottle titrations, the conversion temperature should be the temperature of the water issuing from the bottle spigot. The sample temperatures were measured at the time the samples were drawn from the bottle, but were not used in the conversion from milliliters per liter to micromoles per kilogram because the software was not available. Aberrant drawing temperatures provided an additional flag indicating that a bottle may not have tripped properly. Measured sample temperatures from mid-deep water samples were about 4-7 deg.C warmer than in-situ temperature. Had the conversion with the measured sample temperature been made, converted oxygen values would be about 0.08% higher for a 6 deg.C warming (or about 0.2 uM/Kg for a 250 uM/Kg sample). Oxygen flasks were calibrated gravimetrically with degassed deionized water (DIW) to determine flask volumes at ODF's chemistry laboratory. This is done once before using flasks for the first time and periodically thereafter when a suspect bottle volume is detected. All volumetric glassware used in preparing standards is calibrated as well as the 10 ml Dosimat buret used to dispense standard iodate solution. Iodate standards are pre-weighed in ODF's chemistry laboratory to a nominal weight of 0.44xx grams and exact normality calculated at sea. Potassium iodate (KIO3) is obtained from Johnson Matthey Chemical Co. and is reported by the supplier to be > 99.4% pure. All other reagents are "reagent grade" and are tested for levels of oxidizing and reducing impurities prior to use. 4292 oxygen measurements from the rosette stations were made. Oxygens were not drawn from the large volume stations. No major problems were encountered with the analyses. The oxygen data were used to calibrate the CTD dissolved O2 sensor. C.1.l. Nutrient Analysis Nutrient samples were drawn into 45 ml high density polypropylene, narrow mouth, screw-capped centrifuge tubes which were rinsed three times before filling. Standardizations were performed at the beginning and end of each group of analyses (one cast, usually 36 samples) with a set of an intermediate concentration standard prepared for each run from secondary standards. These secondary standards were in turn prepared aboard ship by dilution from dry, pre-weighed primary standards. Sets of 5-6 different concentrations of shipboard standards were analyzed periodically to determine the deviation from linearity as a function of concentration for each nutrient. Nutrient analyses (phosphate, silicate, nitrate and nitrite) were performed on an ODF-modified 4 channel Technicon AutoAnalyzer II, generally within one hour of the cast. Occasionally some samples were refrigerated at 2 to 6 deg.C for a maximum of 4 hours. The methods used are described by Gordon et al. (1991), Hager et. al (1972), Atlas et. al. (1971). During the first part of the expedition, all peaks were logged manually. Later during the expedition, software was developed and implemented to interpret the colorimeter output from each of the four channels which were digitized and logged automatically by computer (PC), then split into absorbence peaks. All the runs were manually verified. Silicate is analyzed using the technique of Armstrong et al. (1967). Ammonium molybdate is added to a seawater sample to produce silicomolybdic acid which is then reduced to silicomolybdous acid (a blue compound) following the addition of stannous chloride. Tartaric acid is also added to impede PO4 contamination. The sample is passed through a 15 mm flowcell and the absorbence measured at 820nm. ODF's methodology is known to be non- linear at high silicate concentrations (>120 uM); a correction for this non-linearity is applied in ODF's software. Modifications of the Armstrong et al. (1967) techniques for nitrate and nitrite analysis are also used. The seawater sample for nitrate analysis is passed through a cadmium column where the nitrate is reduced to nitrite. Sulfanilamide is introduced, reacting with the nitrite, then N-(1-naphthyl)ethylenediamine dihydrochloride which couples to form a red azo dye. The reaction product is then passed through a 15 mm flowcell and the absorbence measured at 540 nm. The same technique is employed for nitrite analysis, except the cadmium column is not present, and a 50 mm flowcell is used. Phosphate is analyzed using a modification of the Bernhardt and Wilhelms technique, Bernhardt and Wilhelms (1967). Ammonium molybdate is added to the sample to produce phosphomolybdic acid, then reduced to phosphomolybdous acid (a blue compound) following the addition of dihydrazine sulfate. The reaction product is heated to ~55 deg.C to enhance color development, then passed through a 50 mm flowcell and the absorbence measured at 820 nm. Nutrients reported in micromoles per kilogram were converted from micromoles per liter by dividing by sample density calculated at 1 atm pressure, in-situ salinity, and an assumed laboratory temperature of 25 deg.C. Na2SiF6, the silicate primary standard, is obtained from Fluka Chemical Company and Fisher Scientific and is reported by the suppliers to be >98% pure. Primary standards for nitrate (KNO3), nitrite (NaNO2), and phosphate (KH2PO4) are obtained from Johnson Matthey Chemical Co. and the supplier reports purities of 99.999%, 97%, and 99.999%, respectively. 4293 nutrient analyses from the rosette stations were performed. 358 nutrient analyses were performed on the large volume stations. However, these data should only be used as a check of the integrity of the Gerard barrels. The nitrate, phosphate and nitrite are coded "4", bad measurement, as an assurance that these samples will not be used for any other purpose. No major problems were encountered with the measurements. Some concern was expressed in the comparison with historical silicate data. The Chemistry Department at ODF has compared the batch of sodium fluorosilicate (silicate standard) that was sent on the P17N WOCE leg with silicate standards from three other manufacturers, as well as a different lot of silicate standard from the same manufacturer. Our findings indicate that the silicate standard used on the P17N WOCE leg was 0.6% lower than the mean silicate standard value in this comparison. D. Acknowledgments I wish to thank Captain Gomes, the crew of the R/V Thompson and the scientific personnel for making this a pleasant and scientifically successful cruise. E. References Armstrong, F. A. J., Stearns, C. R., and Strickland, J. D. H., "The measurement of upwelling and subsequent biological processes by means of the Technicon Autoanalyzer and associated equipment," Deep-Sea Research, 14, pp. 381-389 (1967). Atlas, E. L., Hager, S. W., Gordon, L. I., and Park, P. K., "A Practical Manual for Use of the Technicon AutoAnalyzer(R) in Seawater Nutrient Analyses Revised," Technical Report 215, Reference 71-22, p. 49, Oregon State University, Department of Oceanography (1971). Bernhardt, H. and Wilhelms, A., "The continuous determination of low level iron, soluble phosphate and total phosphate with the AutoAnalyzer," Technicon Symposia, I, pp. 385-389 (1967). Brown, N. L. and Morrison, G. K., "WHOI/Brown conductivity, temperature and depth microprofiler," Technical Report No. 78-23, Woods Hole Oceanographic Institution (1978). Carpenter, J. H., "The Chesapeake Bay Institute technique for the Winkler dissolved oxygen method," Limnology and Oceanography, 10, pp. 141-143 (1965). Carter, D. J. T., "Computerised Version of Echo-sounding Correction Tables (Third Edition)," Marine Information and Advisory Service, Institute of Oceanographic Sciences, Wormley, Godalming, Surrey. GU8 5UB. U.K. (1980). Culberson, C. H., Knapp, G., Stalcup, M., Williams, R. T., and Zemlyak, F., "A comparison of methods for the determination of dissolved oxygen in seawater," Report WHPO 91-2, WOCE Hydrographic Programme Office (Aug 1991). Gordon, L. I., Jennings, J. C., Jr., Ross, A. A., and Krest, J. M., "A suggested Protocol for Continuous Flow Automated Analysis of Seawater Nutrients in the WOCE Hydrographic Program and the Joint Global Ocean Fluxes Study," Grp. Tech Rpt 92-1, OSU College of Oceanography Descr. Chem Oc. (1992). Hager, S. W., Atlas, E. L., Gordon, L. D., Mantyla, A. W., and Park, P. K., "A comparison at sea of manual and autoanalyzer analyses of phosphate, nitrate, and silicate," Limnology and Oceanography, 17, pp. 931-937 (1972). Key, R. M., Muus, D., and Wells, J., "Zen and the art of Gerard barrel maintenance," WOCE Hydrographic Program Office Technical Report (1991). Millard, R. C., Jr., "CTD calibration and data processing techniques at WHOI using the practical salinity scale," Proc. Int. STD Conference and Workshop, p. 19, Mar. Tech. Soc., La Jolla, Ca. (1982). Owens, W. B. and Millard, R. C., Jr., "A new algorithm for CTD oxygen calibration," Journ. of Am. Meteorological Soc., 15, p. 621 (1985). UNESCO, "Background papers and supporting data on the Practical Salinity Scale, 1978," UNESCO Technical Papers in Marine Science, No. 37, p. 144 (1981). Unesco, 1983. International Oceanographic tables. Unesco Technical Papers in Marine Science, No. 44. Unesco, 1991. Processing of Oceanographic Station Data. Unesco memorgraph By JPOTS editorial panel. F. WHPO Summary Stations number 100 to 120 are non_WOCE stations. They are represented in the sum file to show the cruise was continious. The data will not be avialable in WOCE format. Several data files are associated with this report. They are the P17n.sum, 325021_1.hyd, 325021_1.csl and *.wct files. The 325021_1.sum file contains a summary of the location, time, type of parameters sampled, and other pertinent information regarding each hydrographic station. The 325021_1.hyd file contains the bottle data. The *.wct files are the ctd data for each station. The *.wct files are zipped into one file called 325021_1wct.zip. The P17n.csl file is a listing of ctd and calculated values at standard levels. The following is a description of how the standard levels and calculated values were derived for the 325021_1.csl file: Salinity, Temperature and Pressure: These three values were smoothed from the individual CTD files over the N uniformly increasing pressure levels. using the following binomial filter- t(j) = 0.25ti(j-1) + 0.5ti(j) + 0.25ti(j+1) j=2....N-1 When a pressure level is represented in the *.csl file that is not contained within the ctd values, the value was linearly interpolated to the desired level after applying the binomial filtering. Sigma-theta(SIG-TH:KG/M3), Sigma-2 (SIG-2: KG/M3), and Sigma-4(SIG-4: KG/M3): These values are calculated using the practical salinity scale (PSS-78) and the international equation of state for seawater (EOS-80) as described in the Unesco publication 44 at reference pressures of the surface for SIG-TH; 2000 dbars for Sigma-2; and 4000 dbars for Sigma-4. Gradient Potential Temperature (GRD-PT: C/DB 10-3) is calculated as the least squares slope between two levels, where the standard level is the center of the interval. The interval being the smallest of the two differences between the standard level and the two closest values. The slope is first determined using CTD temperature and then the adiabatic lapse rate is subtracted to obtain the gradient potential temperature. Equations and Fortran routines are described in Unesco publication 44. Gradient Salinity (GRD-S: 1/DB 10-3) is calculated as the least squares slope between two levels, where the standard level is the center of the standard level and the two closes values. Equations and Fortran routines are described in Unesco publication 44. Potential Vorticity (POT-V: 1/ms 10-11) is calculated as the vertical component ignoring contributions due to relative vorticity, i.e. pv=fN2/g, where f is the coriolius parameter, N is the buoyancy frequency (data expressed as radius/sec), and g is the local acceleration of gravity. Buoyancy Frequency (B-V: cph) is calculated using the adiabatic leveling method, Fofonoff (1985) and Millard, Owens and Fofonoff (1990). Equations and Fortran routines are described in Unesco publication 44. Potential Energy (PE: J/M2: 10-5) and Dynamic Height (DYN-HT: M) are calculated by integrating from 0 to the level of interest. Equations and Fortran routines are described in Unesco publication 44. Neutral Density (GAMMA-N: KG/M3) is calculated with the program GAMMA-N (Jackett and McDougall) version 1.3 Nov. 94. G. DQE Evaulations CTD and hydrographic DQE by Micho Aoyama General: The data quality of WOCE P17N CTD data (EXPOCODE: 325021/1) and the CTD salinity and oxygen found in dot sea file are examined. . The individual 2 dbar profiles were observed in temperature, salinity and oxygen by comparing the profiles obtained at the nearby stations. The CTD salinity and oxygen calibrations are examined using the water sample data file p17n.mka. DQE used the original water sample data flagged "2" only for the DQE work. Details CTD profiles The temperature and salinity profiles generally look good. Since the data originator has done a pretty reliable work in evaluating their data, CTD data flagged "2-good" has a pretty good quality. Although the data originator has solved some CTD salinity offset problems well, DQE would like to complain of CTD conductivity offsets adapted by the data originator as described in the next section. Evaluation of CTD calibrations to water samples: Salinity calibration: The onboard calibration for salinity looks good in general. Standard deviation of Ds, Ds = CTD salinity in dot sea file - bottle salinity, is 0.00467 psu for all data and 0.00112 pss for deeper than 2000 dbar, respectively. The histogram of Ds for all depths shows a symmetric distribution (fig. 1). Since the larger difference are shallower layers, larger Ds disappeared in the histogram of Ds for deeper than 2000 dbar (fig. 2). DQE, however, observed the non-symmetric distribution of Ds in deep salinity fit. DQE observed that Ds vs. pressure plot shows a small bias of ca. -0.001 psu in the deeper than 2000 dbar, while it shows a small bias of 0.001 psu in the shallower than 1500 dbar (fig. 3). DQE also observed that the Ds in deep salinity fit shows a larger discontinuity at several stations as shown in fig 4 considering the accuracy and precision of CTD salinity for the WOCE one time survey standards for CTD measurements . The magnitude of the discontinuity and the stations are summarized in table 1 together with the problems recorded in table 1.7.0 in the cruise report; Table 7: Summary of Ds offset larger than 0.002 psu. ---------------------------------------------------------------------------------------------------------------------- stations Ds offset related comment in cruise report ---------------------------------------------------------------------------------------------------------------------- a) between stn. 11 and 12 ca. 0.004 psu sal. offset at stn. 11 b) between stn. 24 and 25 ca. 0.002 psu power outage at stn. 24 c) between stn. 26 and 27 ca. -0.002 psu power outage at stn. 27 d) between stn. 45 and 47 ca. -0.003 psu sal. offset at stn. 47 e) between stn. 47 and 48 ca. 0.002 psu sal. offset at stn. 47 f) between stn. 55 and 56 ca. 0.003 psu no problem recorded g) between stn. 79 and 81 ca. -0.002 psu sal. offset at stn. 80 h) between stn. 121 and 122 ca. -0.003 psu no problem recorded i) between stn. 126 and 128 ca. 0.003 psu no problem recorded j) between stn. 131 and 133 ca. -0.002 psu no problem recorded k) between stn. 135 and 136 ca. -0.002 psu no problem recorded --------------------------------------------------------------------------------------------------------------------- DQE thinks that something might have occurred to the conductivity sensor at the stations listed in above table . For an example, DQE thinks that the smoothed offset for the station group 068-097 is not in good fit. Then, Ds for stations 068-097 has a clear trend from -0.001 psu to 0.001 psu between 068 and 079, thereafter Ds for stations 080-097 shows clear trend from -0.001 psu to 0.001 psu again. DQE think this can be explained by the wrong estimation of the slope of the CTD conductivity offset due to the unsuitable station grouping. If the data originator will divide this station group of 068-097 into 2 station groups of 068-079 and 080-097 and apply new CTD conductivity offsets to CTD conductivities in new 2 station groups, the trend of Ds will be expected to be smaller remarkably. DQE suggests that the CTD conductivity offsets should be applied to CTD conductivity in more station groups taking into account the Ds trend as shown in fig. 4. DQE also suggests additional calibration for decreasing the pressure dependency of Ds will improve the quality of CTD salinity. Oxygen calibration; Standard deviation of Dox, Dox = CTD oxygen in dot sea file - bottle oxygen, is 4.49 umol/kg for all depths and the standard deviation of Dox is 0.89 umol/kg for deeper than 200 dbar. These confirms the good oxygen calibration work. DQE observed no significant station dependency of Dox. DQE observes "weak pressure dependency" of Dox in fig. 5. Although the range of dependency is ca. 1 u mol/kg, if PI of CTDO could correct this tendency, the quality of CTD oxygen data will be further improved. The following are some specific problems that should be looked at: Stn. 70 at 4262-4848 dbar and 4150-4172 dbar. CTD salinity looks shifted 0.002 higher. Suggest flg. "3" Stn. 138 at 3126 dbar and 3128 dbar; CTD oxygen spikes are observed. Suggest flg. "3" Comments on DQ evaluation of WOCE P17N Hydrographic data (EXPOCODE: 325021/1). Michio AOYAMA The data quality of the hydrographic data of the WOCE P17N cruise (EXPOCODE: 325021/1) are examined.The data files for this DQE work was P17N.sum and P17N.mka ( this P17N.mka file is created for DQE, then it has a new column of quality 2 word) provided by WHPO. General; The station spacing was less than 30 nautical miles and the sampling layer spacing was kept ca. 250 dbar in the deeper layers during this P17N cruise. The ctd lowering were made to within 2 -19 meters to the sea bottom. Since the data originators have done a pretty reliable work in evaluating their data, hydrographic data flagged "2-good" has a pretty good quality. This high density and high quality data will improve our knowledge on the eastern North Pacific following the update of Pacific Ocean deep water data set. DQE used the data flagged "2" by data originator for this DQE work. DQE examined 6 profiles, 6 property vs. theta plots, and 2 property vs. property plots as listed below; salinity, oxygen, silicate, nitrate,nitrite and phosphate profiles salinity, oxygen, silicate, nitrate,nitrite and phosphate vs. theta plot nitrate vs. phosphate plot salinity vs. silicate plot Salinity; Bottle salinity profile looks good. Salinity vs. oxygen and theta vs. salinity plots also looks reasonable. DQE thinks that the flags of the bottle salinity data are reliable. Oxygen; Bottle oxygen profile looks good. Salinity vs. oxygen and theta vs. oxygen plots also looks reasonable. DQE thinks that the flags of the bottle oxygen data are reliable. Nutrients; Since nutrient PI has done a pretty reliable work in evaluating their data, the profiles of silicate, nitrate, nitrite and phosphate looks pretty well. Nitrate vs. phosphate plot and silicate vs. salinity plot also look pretty reasonable. (The data originator was concerned in the comparison with historical silica data in the cruise report. DQE also observes a larger difference between P17N silica and P1 silica data at the crossing. However, a verification of overall traceability among the WOCE cruises and historical data might depend a further work in the near future.) The following are some specific problems that should be looked at: STNNBR XX/ CASTNO X/ SAMPNO XX at XXXX dbar: 9/1/36 at 3646 dbar: Silicate concentration looks higher. Suggest flag "3". 44/1/36 at 4207 dbar: Bottle salinity looks higher. Suggest flag "3". 56/1/24 at 1926 dbar: Bottle salinity looks lower. Suggest flag "3". 56/1/27 at 2220 dbar: Bottle salinity looks lower. Suggest flag "3". 78/2/36 at 4703 dbar: Bottle salinity looks lower. Suggest flag "3".