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Metadata Report for BODC Series Reference Number 860915

Metadata Summary

Data Description

Data Category CTD or STD cast
Instrument Type
Neil Brown MK3 CTD  CTD; water temperature sensor; salinity sensor; dissolved gas sensors
SeaTech transmissometer  transmissometers
Chelsea Technologies Group Aquatracka fluorometer  fluorometers
Instrument Mounting research vessel
Originating Country United Kingdom
Originator Prof John Simpson
Originating Organization University of Wales, Bangor School of Ocean Sciences (now Bangor University School of Ocean Sciences)
Processing Status banked
Online delivery of data Download available - Ocean Data View (ODV) format
Project(s) Land Ocean Interaction Study (LOIS)

Data Identifiers

Originator's Identifier CP68
BODC Series Reference 860915

Time Co-ordinates(UT)

Start Time (yyyy-mm-dd hh:mm) 1996-07-21 06:52
End Time (yyyy-mm-dd hh:mm) -
Nominal Cycle Interval 2.0 decibars

Spatial Co-ordinates

Latitude 56.66283 N ( 56° 39.8' N )
Longitude 9.14217 W ( 9° 8.5' W )
Positional Uncertainty 0.0 to 0.01 n.miles
Minimum Sensor or Sampling Depth 2.97 m
Maximum Sensor or Sampling Depth 865.16 m
Minimum Sensor or Sampling Height -3.36 m
Maximum Sensor or Sampling Height 858.83 m
Sea Floor Depth 861.8 m
Sea Floor Depth Source DATAHEAD
Sensor or Sampling Distribution Variable common depth - All sensors are grouped effectively at the same depth, but this depth varies significantly during the series
Sensor or Sampling Depth Datum Instantaneous - Depth measured below water line or instantaneous water body surface
Sea Floor Depth Datum Instantaneous - Depth measured below water line or instantaneous water body surface


BODC CODERankUnitsTitle
ATTNZR011per metreAttenuation (red light wavelength) per unit length of the water body by transmissometer
CPHLPR011Milligrams per cubic metreConcentration of chlorophyll-a {chl-a CAS 479-61-8} per unit volume of the water body [particulate >unknown phase] by in-situ chlorophyll fluorometer
DOXYPR011Micromoles per litreConcentration of oxygen {O2 CAS 7782-44-7} per unit volume of the water body [dissolved plus reactive particulate phase] by in-situ Beckmann probe
OXYSBB011PercentSaturation of oxygen {O2 CAS 7782-44-7} in the water body [dissolved plus reactive particulate phase] by in-situ Beckmann probe and computation from concentration using Benson and Krause algorithm
POATCV011per metrePotential attenuance (unspecified wavelength) per unit length of the water body by transmissometer and computation using P-EXEC algorithm
POTMCV011Degrees CelsiusPotential temperature of the water body by computation using UNESCO 1983 algorithm
PRESPR011DecibarsPressure (spatial coordinate) exerted by the water body by profiling pressure sensor and correction to read zero at sea level
PSALST011DimensionlessPractical salinity of the water body by CTD and computation using UNESCO 1983 algorithm
SIGTPR011Kilograms per cubic metreSigma-theta of the water body by CTD and computation from salinity and potential temperature using UNESCO algorithm
TEMPST011Degrees CelsiusTemperature of the water body by CTD or STD

Definition of Rank

  • Rank 1 is a one-dimensional parameter
  • Rank 2 is a two-dimensional parameter
  • Rank 0 is a one-dimensional parameter describing the second dimension of a two-dimensional parameter (e.g. bin depths for moored ADCP data)

Problem Reports

No Problem Report Found in the Database

Data Access Policy

Open Data

These data have no specific confidentiality restrictions for users. However, users must acknowledge data sources as it is not ethical to publish data without proper attribution. Any publication or other output resulting from usage of the data should include an acknowledgment.

If the Information Provider does not provide a specific attribution statement, or if you are using Information from several Information Providers and multiple attributions are not practical in your product or application, you may consider using the following:

"Contains public sector information licensed under the Open Government Licence v1.0."

Narrative Documents

Neil Brown MK3 CTD

The Neil Brown MK3 conductivity-temperature-depth (CTD) profiler consists of an integral unit containing pressure, temperature and conductivity sensors with an optional dissolved oxygen sensor in a pressure-hardened casing. The most widely used variant in the 1980s and 1990s was the MK3B. An upgrade to this, the MK3C, was developed to meet the requirements of the WOCE project.

The MK3C includes a low hysteresis, titanium strain gauge pressure transducer. The transducer temperature is measured separately, allowing correction for the effects of temperature on pressure measurements. The MK3C conductivity cell features a free flow, internal field design that eliminates ducted pumping and is not affected by external metallic objects such as guard cages and external sensors.

Additional optional sensors include pH and a pressure-temperature fluorometer. The instrument is no longer in production, but is supported (repair and calibration) by General Oceanics.


These specification apply to the MK3C version.

Pressure Temperature Conductivity

6500 m

3200 m (optional)

-3 to 32°C 1 to 6.5 S cm-1

0.0015% FS

0.03% FS < 1 msec


0.003°C < 30 msec

0.0001 S cm-1

0.0003 S cm-1 < 30 msec

Further details can be found in the specification sheet.

Aquatracka fluorometer

The Chelsea Instruments Aquatracka is a logarithmic response fluorometer. It uses a pulsed (5.5 Hz) xenon light source discharging between 320 and 800 nm through a blue filter with a peak transmission of 420 nm and a bandwidth at half maximum of 100 nm. A red filter with sharp cut off, 10% transmission at 664 nm and 678 nm, is used to pass chlorophyll-a fluorescence to the sample photodiode.

The instrument may be deployed either in a through-flow tank, on a CTD frame or moored with a data logging package.

Further details can be found in the manufacturer's specification sheet.

SeaTech Transmissometer


The transmissometer is designed to accurately measure the the amount of light transmitted by a modulated Light Emitting Diode (LED) through a fixed-length in-situ water column to a synchronous detector.


  • Water path length: 5 cm (for use in turbid waters) to 1 m (for use in clear ocean waters).
  • Beam diameter: 15 mm
  • Transmitted beam collimation: <3 milliradians
  • Receiver acceptance angle (in water): <18 milliradians
  • Light source wavelength: usually (but not exclusively) 660 nm (red light)


The instrument can be interfaced to Aanderaa RCM7 current meters. This is achieved by fitting the transmissometer in a slot cut into a customized RCM4-type vane.

A red LED (660 nm) is used for general applications looking at water column sediment load. However, green or blue LEDs can be fitted for specilised optics applications. The light source used is identified by the BODC parameter code.

Further details can be found in the manufacturer's Manual.

RRS Challenger 128A CTD Data Documentation

Components of the CTD data set

The CTD data set for cruise CH128A consists of 88 vertical profiles. The data parameters are temperature, salinity, upwelling and downwelling irradiance, dissolved oxygen, chlorophyll and optical attenuance.

Data Acquisition and On-Board Processing


The CTD profiles were taken with an RVS Neil Brown Mk3B CTD incorporating a pressure sensor, conductivity cell, platinum resistance thermometer and a Beckmann dissolved oxygen sensor. Water was forced over the oxygen membrane by a SeaBird submersible pump. The CTD unit was mounted vertically in the centre of a protective cage approximately 1.5m square. Attached to the bars of the frame were a Chelsea Instruments Aquatracka fluorometer and a SeaTech red light (661 nm) transmissometer with a 25cm path length.

Above the frame was a General Oceanics rosette sampler fitted with twelve 10-litre Niskin water bottles. The bases of the bottles were 0.75 metres above the pressure head and their tops 1.55 metres above it. One bottle was fitted with a holder for twin digital reversing thermometers mounted 1.38 metres above the CTD temperature sensor.

Above the rosette was a PML 2pi PAR (photosynthetically available radiation) sensor pointing upwards to measure downwelling scalar irradiance. A second 2pi PAR sensor, pointing downwards, was fitted to the bottom of the cage to measure upwelling scalar irradiance. It should be noted that these sensors were vertically separated by 2 metres with the upwelling sensor 0.2 metres below the pressure head and the downwelling sensor 1.75 metres above it.

No account has been taken of rig geometry in the compilation of the CTD data set. However, all water bottle sampling depths have been corrected for rig geometry and represent the true position of the midpoint of the water bottle in the water column.

Data Acquisition

On each cast, the CTD was lowered continuously at 0.5 to 1.0 ms-1 to the closest comfortable proximity to the sea floor. The upcast was done in stages between the bottle firing depths.

Data were logged by the RVS ABC data logging system. Output channels from the deck unit were logged at 32 Hz by a microprocessor interface (the Level A) which passed time-stamped averaged cycles at 1 Hz to a Sun workstation (the Level C) via a buffering system (the Level B).

On-Board Data Processing

The raw data comprised ADC counts. These were converted into engineering units (volts for PAR meters, fluorometer and transmissometer; ml/l for oxygen; mmho/cm for conductivity; °C for temperature; decibars for pressure) by the application of laboratory determined calibrations. Salinity (Practical Salinity Units as defined in Fofonoff and Millard, 1983) was calculated from the conductivity ratios (conductivity/42.914) and a time lagged temperature using the function described in UNESCO Report 37 (1981).

The data set was submitted to BODC in this form on Quarter Inch Cartridge tapes in RVS internal format for post-cruise processing and data banking.

Post-Cruise Processing and Calibration at BODC


The data were converted into the BODC internal format (PXF) to allow the use of in-house software tools, notably the workstation graphics editor. In addition to reformatting, the transfer program applied the following modifications to the data:

  • Dissolved oxygen was converted from ml/l to µM by multiplying the values by 44.66.
  • Transmissometer voltages were corrected to the manufacturer's specified voltage by ratio using transmissometer air readings taken during the cruise.
  • Transmissometer voltages were converted to percentage transmission by multiplying them by a factor of 20.
  • The transmissometer data were converted to attenuance using the algorithm:-
attenuance (m-1) = -4 loge (% transmission/100)


Reformatted CTD data were transferred onto a high-speed graphics workstation. Using a custom in-house graphics editor, downcasts and upcasts were differentiated and the limits of the downcasts and upcasts were manually flagged.

Spikes on all the downcast channels were manually flagged. No data values were edited or deleted; flagging was achieved by modification of the associated quality control flag.

The pressure ranges over which the bottle samples had been collected were logged by manual interaction with the software. Usually, clusters of points recorded while the CTD was held stationary were used to determine this. These pressure ranges were subsequently used, in conjunction with a geometrical correction for the position of the water bottles with respect to the CTD pressure transducer, to determine the pressure range of data to be averaged for calibration values.

For this cruise, the RVS Neil Brown Mk 3B CTD system was equipped with a SeaBird pump, which sent water at a constant rate through the housing containing the existing Beckman oxygen electrode. Problems associated with the plumbing of the pump to the oxygen probe resulted in many profiles only recording good oxygen data on upcasts. To overcome this, the upcast data for oxygen, temperature and salinity channels were flagged to remove any spikes. The downcast oxygen values loaded into ORACLE were then replaced where necessary by upcast oxygen data using isopycnal (rather than pressure) matching to determine the replacement values to be used.

Once screened on the workstation, the CTD downcasts were loaded into a database under the ORACLE Relational Database Management System.


With the exception of pressure, calibrations were done by comparison of CTD data against measurements made on water bottle samples or from the reversing thermometers mounted on the water bottles as in the case of temperature. In general, values were averaged from the CTD downcasts but where visual inspection of the data showed significant hysteresis values were manually extracted from the CTD upcasts.

All calibrations described here have been applied to the data except for the calibration to express attenuance in terms of suspended matter concentration.


The pressure offset was determined by looking at the pressures recorded when the CTD was clearly logging in air (readily apparent from the conductivity channel). The following correction was calculated from 14 values:

Pcorr = P - 0.16

The CTD temperature was compared with readings from the digital reversing thermometers attached to the water bottles. Normal BODC practice is to use this comparison as a check to ensure against CTD malfunction rather than a calibration because the Neil Brown CTD thermometer is considered more accurate than the SIS digital reversing thermometers.

However, the CTD used on this cruise had not been accurately calibrated by RVS and the temperature data supplied to BODC were based on a nominal calibration. Consequently, the reversing thermometer data were used to recalibrate the CTD temperature data and the following correction has been applied:

Tcorr = T - 0.032 (standard deviation 0.006)

During screening an offset was noted in the salinity trace. This was attributed to the conductivity cell contamination. The following correction has been applied:

CP57 0.041 PSU added between 158.0 db and 355.6 db

Salinity was calibrated against water bottle samples measured on the Guildline 55358 AutoLab Salinometer during the cruise. Samples were collected in glass bottles filled to just below the neck and sealed with plastic stoppers. Batches of samples were left for at least 24 hours to reach thermal equilibrium in the lab containing the salinometer before analysis.

The correction determined for this cruise was:

Scorr = S + 0.088 (standard deviation 0.003)
Upwelling and Downwelling Irradiance

The PAR voltages were converted to W m-2 using the following equations determined in August 1995 supplied by RVS.

Upwelling (#10): PAR (W m-2) = exp (-4.98*volts + 6.565)/100.0
Downwelling (#12): PAR (W m-2) = exp (-4.92*volts + 6.506)/100.0

Note that these sensors have been empirically calibrated to obtain a conversion from W/m2 into µE/m2/s, which may be effected by multiplying the data given by 3.75.

Optical Attenuance and Suspended Matter

The air correction applied for this cruise was based on an air reading obtained during the cruise (4.736V). The manufacturer's voltage for the instrument used (SN079D) was 4.744V.

Large volume samples were taken for gravimetric analysis of the suspended particulate matter concentration. These were used to generate calibrations that expressed attenuance in terms of suspended particulate matter concentrations.

Robin McCandliss (University of Wales, Bangor) undertook this work, under the supervision of Sarah Jones. The optimal approach developed was to base the calibration on samples taken from near the seabed (i.e. those with the minimum content of fluorescent material). The data from all SES cruises where SPM samples were taken were pooled to derive the calibration equation:

SPM (mg/l) = (2.368*Atten) - 0.801 (R2 = 79%)

This calibration is valid for all SES cruises after and including cruise Charles Darwin CD93A. The clear water attenuance predicted by the equation is 0.336 per m, which agrees well with literature values.

No attempt has been made to replace attenuance by SPM concentration in the final data set. However, users may use the equation above to compute an estimated SPM channel from attenuance when required.


200ml of seawater collected at several depths on each cast were filtered and the papers frozen for acetone extraction and fluorometric analysis on land. A relatively small number of samples were taken on CH128B. Consequently, the data from both legs of CH128 were pooled for the calibration.

The extracted chlorophyll concentrations (range 0.1 to 2.94 mg m-3) were regressed against the corresponding fluorometer voltages, giving the following calibration which has been applied to the data:

Chlorophyll (mg m-3) = exp (1.33 * volts - 2.75) (R2 = 56.7%, n = 176)
Dissolved Oxygen

Dissolved oxygen concentrations were determined by micro-Winkler titration of seawater samples taken from a range of depths on several CTD casts. These values were compared with oxygen readings derived from the oxygen sensor membrane current, oxygen sensor temperature, sea temperature and salinity values recorded by the CTD on the upcast. Hilary Wilson (University of Wales, Bangor), under the supervision of Dr. Paul Tett, carried out this work. The following equation was supplied to BODC and the coefficients A and B were applied to the data:

[O2] = (A*C + B)* S' ml/l
where A = 2.1507689 (casts CP1-CP80) or 3.39847069 (casts CP81-CP90)
  C = oxygen sensor current (µA)
  B = -0.1448435 (casts CP1-CP80) or -1.2152591 (casts CP81-CP90)
  S'= oxygen saturation concentration (a function of water temperature and salinity).

Finally, the data were converted to µM by multiplication by 44.66.

The calibration coefficients used for casts CP1-CP80 were derived using the pooled data from 4 of the profiles from which bottle oxygen samples were taken. The calibration for CP81-CP90 was based on data from cast CP81. Individual calibrations were derived for each of these profiles. These are included below for reference. However, please note that the whole cruise coefficients given above were applied to all profiles in the database.

CP5  2.33219833  -0.2623257
CP64  2.15424386  -0.1062559
CP65  2.34197522  -0.2343615
CP69  2.03641103  -0.0567426
CP81  3.39847069  -1.2152591

Considerable manipulation of the oxygen data, such as the substitution of downcast data by isopycnal-matched upcast data, was required to produce the oxygen data channel in the final data set. This, combined with the uncertainties involved in the calibration of oxygen data, might mean that some users would wish to re-examine the oxygen processing. To facilitate this, BODC have systematically archived the raw data (including oxygen current and temperature) from both upcasts and downcasts. These data are available on request.

During the visual inspection of the oxygen data from this cruise it was noticed that there was a significant difference between the downcast and upcast data (sometimes 1-200 µM different at the surface). This difference was far greater than other SES cruises and was present, though it diminished in magnitude with depth, for the whole cast. Consequently, all the data in the final data set have been derived from the upcast rather than the odd 'patch' as in CH121B and CH126B. Looking at the data leaves a nagging doubt that the oxygen sensor was being very slow to equilibrate and there is no concrete evidence that it had reached equilibrium by the start of the upcast. Users are therefore recommended to use the CTD oxygen data from this cruise with a degree of caution.

Data Reduction

Once all screening and calibration procedures were completed, the data set was binned to 2 db (casts deeper than 100 db) or 1 db (casts shallower than 100 db). The binning algorithm excluded any data points flagged suspect and attempted linear interpolation over gaps up to 3 bins wide. If any gaps larger than this were encountered, the data in the gaps were set null.

Oxygen saturation has been computed using the algorithm of Benson and Krause (1984).

Data Warnings

There is strong evidence that the oxygen sensor was exceptionally slow to equilibrate. Although the data presented in the final data set have been taken from the upcast, users are recommended to use the oxygen data from this cruise with caution.


Benson B.B. and Krause D. jnr. 1984. The concentration and isotopic fractionation of oxygen dissolved in fresh water and sea water in equilibrium with the atmosphere. Limnol. Oceanogr. 29 pp.620-632.

Fofonoff N.P., and Millard Jr., R.C. 1982. Algorithms for Computation of Fundamental Properties of Seawater. UNESCO Technical Papers in Marine Science 44.

Project Information

Land Ocean Interaction Study (LOIS)


The Land Ocean Interaction Study (LOIS) was a Community Research Project of the Natural Environment Research Council (NERC). The broad aim of LOIS was to gain an understanding of, and an ability to predict, the nature of environmental change in the coastal zone around the UK through an integrated study from the river catchments through to the shelf break.

LOIS was a collaborative, multidisciplinary study undertaken by scientists from NERC research laboratories and Higher Education institutions. The LOIS project was managed from NERC's Plymouth Marine Laboratory.

The project ran for six years from April 1992 until April 1998 with a further modelling and synthesis phase beginning in April 1998 and ending in April 2000.

Project Structure

LOIS consisted of the following components:

  • River-Atmosphere-Coast Study (RACS)
    • RACS(A) - Atmospheric sub-component
    • RACS(C) - Coasts sub-component
    • RACS(R) - Rivers sub-component
    • BIOTA - Terrestrial salt marsh study
  • Land Ocean Evolution Perspective Study (LOEPS)
  • Shelf-Edge Study (SES)
  • North Sea Modelling Study (NORMS)
  • Data Management (DATA)

Marine Fieldwork

Marine field data were collected between September 1993 and September 1997 as part of RACS(C) and SES. The RACS data were collected throughout this period from the estuaries and coastal waters of the UK North Sea coast from Great Yarmouth to the Tweed. The SES data were collected between March 1995 and September 1996 from the Hebridean slope. Both the RACS and SES data sets incorporate a broad spectrum of measurements collected using moored instruments and research vessel surveys.

Data Activity or Cruise Information


Cruise Name CH128A
Departure Date 1996-07-10
Arrival Date 1996-07-26
Principal Scientist(s)John H Simpson (University of Wales, Bangor School of Ocean Sciences)
Ship RRS Challenger

Complete Cruise Metadata Report is available here

Fixed Station Information

Fixed Station Information

Station NameLOIS (SES) Repeat Section N
CategoryOffshore route/traverse

LOIS (SES) Repeat Section N

Section N was one of four repeat sections sampled during the Land-Ocean Interaction Study (LOIS) Shelf Edge Study (SES) project between March 1995 and September 1996.

The CTD measurements collected at repeat section N, on the Hebridean Slope, lie within a box bounded by co-ordinates 56° 35.4' N, 11° 0.0' W at the southwest corner and 57° 0.0' N, 8° 54.6' W at the northeast corner.

Cruises occupying section N

Cruise Start Date End Date
Charles Darwin 91B 22/03/1995 02/04/1995
Charles Darwin 92B 13/04/1995 02/05/1995
Charles Darwin 93A 07/05/1995 16/05/1995
Charles Darwin 93B 16/05/1995 30/05/1995
Challenger 120 18/07/1995 06/08/1995
Challenger 121A 10/08/1995 18/08/1995
Tydeman SESAME-1 10/08/1995 11/09/1995
Challenger 121B 18/08/1995 01/09/1995
Challenger 121C 01/09/1995 10/09/1995
Challenger 123B 01/12/1995 15/12/1995
Challenger 124 08/01/1996 27/01/1996
Challenger 125A 31/01/1996 12/02/1996
Challenger 125B 13/02/1996 03/03/1996
Challenger 126A 11/04/1996 26/04/1996
Challenger 126B 27/04/1996 12/05/1996
Challenger 128A 10/07/1996 26/07/1996
Challenger 128B 26/07/1996 08/08/1996

Related Fixed Station activities are detailed in Appendix 1

BODC Quality Control Flags

The following single character qualifying flags may be associated with one or more individual parameters with a data cycle:

Flag Description
Blank Unqualified
< Below detection limit
> In excess of quoted value
A Taxonomic flag for affinis (aff.)
B Beginning of CTD Down/Up Cast
C Taxonomic flag for confer (cf.)
D Thermometric depth
E End of CTD Down/Up Cast
G Non-taxonomic biological characteristic uncertainty
H Extrapolated value
I Taxonomic flag for single species (sp.)
K Improbable value - unknown quality control source
L Improbable value - originator's quality control
M Improbable value - BODC quality control
N Null value
O Improbable value - user quality control
P Trace/calm
Q Indeterminate
R Replacement value
S Estimated value
T Interpolated value
U Uncalibrated
W Control value
X Excessive difference

SeaDataNet Quality Control Flags

The following single character qualifying flags may be associated with one or more individual parameters with a data cycle:

Flag Description
0 no quality control
1 good value
2 probably good value
3 probably bad value
4 bad value
5 changed value
6 value below detection
7 value in excess
8 interpolated value
9 missing value
A value phenomenon uncertain
B nominal value
Q value below limit of quantification

Appendix 1: LOIS (SES) Repeat Section N

Related series for this Fixed Station are presented in the table below. Further information can be found by following the appropriate links.

If you are interested in these series, please be aware we offer a multiple file download service. Should your credentials be insufficient for automatic download, the service also offers a referral to our Enquiries Officer who may be able to negotiate access.

Series IdentifierData CategoryStart date/timeStart positionCruise
847949CTD or STD cast1995-03-25 11:30:0056.62217 N, 8.92983 WRRS Charles Darwin CD91B
1671054Water sample data1995-03-25 11:48:0056.62223 N, 8.92982 WRRS Charles Darwin CD91B
847950CTD or STD cast1995-03-26 09:26:0056.6285 N, 9.00283 WRRS Charles Darwin CD91B
1671078Water sample data1995-03-26 09:36:0056.62858 N, 9.0029 WRRS Charles Darwin CD91B
847913CTD or STD cast1995-03-26 18:40:0056.63717 N, 9.016 WRRS Charles Darwin CD91B
1671091Water sample data1995-03-26 18:55:0056.6372 N, 9.01607 WRRS Charles Darwin CD91B
847998CTD or STD cast1995-03-29 16:38:0056.747 N, 9.42817 WRRS Charles Darwin CD91B
434873CTD or STD cast1995-04-17 07:39:0056.7167 N, 9.4 WRRS Charles Darwin CD92B
434885CTD or STD cast1995-04-17 09:50:0056.68 N, 9.25 WRRS Charles Darwin CD92B
434897CTD or STD cast1995-04-17 17:34:0056.605 N, 8.935 WRRS Charles Darwin CD92B
434904CTD or STD cast1995-04-17 18:24:0056.62 N, 9.0063 WRRS Charles Darwin CD92B
434916CTD or STD cast1995-04-17 19:04:0056.6242 N, 9.0225 WRRS Charles Darwin CD92B
434928CTD or STD cast1995-04-17 19:54:0056.635 N, 9.0667 WRRS Charles Darwin CD92B
434941CTD or STD cast1995-04-17 20:57:0056.6467 N, 9.1125 WRRS Charles Darwin CD92B
434953CTD or STD cast1995-04-18 12:21:0056.6633 N, 9.1667 WRRS Charles Darwin CD92B
435053CTD or STD cast1995-04-21 06:50:0056.605 N, 8.935 WRRS Charles Darwin CD92B
435065CTD or STD cast1995-04-21 08:00:0056.62 N, 9.0063 WRRS Charles Darwin CD92B
435077CTD or STD cast1995-04-21 09:45:0056.6242 N, 9.0225 WRRS Charles Darwin CD92B
435089CTD or STD cast1995-04-21 10:34:0056.635 N, 9.0667 WRRS Charles Darwin CD92B
435090CTD or STD cast1995-04-21 12:37:0056.6467 N, 9.1125 WRRS Charles Darwin CD92B
435108CTD or STD cast1995-04-21 14:25:0056.6633 N, 9.1667 WRRS Charles Darwin CD92B
435121CTD or STD cast1995-04-21 16:25:0056.68 N, 9.25 WRRS Charles Darwin CD92B
435133CTD or STD cast1995-04-21 18:47:0056.7188 N, 9.4083 WRRS Charles Darwin CD92B
435458CTD or STD cast1995-04-30 18:15:0056.7188 N, 9.4083 WRRS Charles Darwin CD92B
435471CTD or STD cast1995-04-30 20:41:0056.68 N, 9.25 WRRS Charles Darwin CD92B
435483CTD or STD cast1995-04-30 22:17:0056.6633 N, 9.1667 WRRS Charles Darwin CD92B
435495CTD or STD cast1995-04-30 23:41:0056.6467 N, 9.1125 WRRS Charles Darwin CD92B
435502CTD or STD cast1995-05-01 00:41:0056.635 N, 9.0667 WRRS Charles Darwin CD92B
435514CTD or STD cast1995-05-01 01:43:0056.6242 N, 9.0225 WRRS Charles Darwin CD92B
435526CTD or STD cast1995-05-01 02:27:0056.62 N, 9.0063 WRRS Charles Darwin CD92B
435538CTD or STD cast1995-05-01 03:11:0056.605 N, 8.935 WRRS Charles Darwin CD92B
852386CTD or STD cast1995-05-12 00:04:0056.71983 N, 9.39983 WRRS Charles Darwin CD93A
852398CTD or STD cast1995-05-12 09:56:0056.73617 N, 9.50167 WRRS Charles Darwin CD93A
852835CTD or STD cast1995-05-12 12:48:0056.73817 N, 9.49467 WRRS Charles Darwin CD93A
852405CTD or STD cast1995-05-12 16:08:0056.60683 N, 8.92467 WRRS Charles Darwin CD93A
852417CTD or STD cast1995-05-12 19:32:0056.6135 N, 8.9455 WRRS Charles Darwin CD93A
852491CTD or STD cast1995-05-12 20:43:0056.622 N, 8.99467 WRRS Charles Darwin CD93A
852430CTD or STD cast1995-05-12 21:36:0056.61783 N, 9.0095 WRRS Charles Darwin CD93A
852509CTD or STD cast1995-05-12 22:33:0056.62633 N, 9.01767 WRRS Charles Darwin CD93A
852510CTD or STD cast1995-05-12 23:35:0056.63833 N, 9.073 WRRS Charles Darwin CD93A
852442CTD or STD cast1995-05-13 01:04:0056.65283 N, 9.10633 WRRS Charles Darwin CD93A
852534CTD or STD cast1995-05-13 04:06:0056.67133 N, 9.20717 WRRS Charles Darwin CD93A
852454CTD or STD cast1995-05-13 09:53:0056.73017 N, 9.42817 WRRS Charles Darwin CD93A
852233CTD or STD cast1995-05-13 12:20:0056.71567 N, 9.40917 WRRS Charles Darwin CD93A
852245CTD or STD cast1995-05-13 19:29:0056.62167 N, 8.99317 WRRS Charles Darwin CD93A
852466CTD or STD cast1995-05-13 21:50:0056.63033 N, 9.00117 WRRS Charles Darwin CD93A
852257CTD or STD cast1995-05-14 00:27:0056.7165 N, 9.36633 WRRS Charles Darwin CD93A
852269CTD or STD cast1995-05-14 02:34:0056.69933 N, 9.323 WRRS Charles Darwin CD93A
852270CTD or STD cast1995-05-14 04:31:0056.69017 N, 9.2485 WRRS Charles Darwin CD93A
852478CTD or STD cast1995-05-14 06:37:0056.639 N, 9.06667 WRRS Charles Darwin CD93A
852282CTD or STD cast1995-05-14 07:48:0056.62717 N, 9.01667 WRRS Charles Darwin CD93A
852294CTD or STD cast1995-05-14 09:04:0056.62917 N, 9.0235 WRRS Charles Darwin CD93A
852699CTD or STD cast1995-05-14 13:52:0056.6285 N, 9.00933 WRRS Charles Darwin CD93A
848989CTD or STD cast1995-05-18 23:56:0056.60333 N, 8.93983 WRRS Charles Darwin CD93B
848990CTD or STD cast1995-05-19 01:07:0056.6175 N, 8.99217 WRRS Charles Darwin CD93B
849434CTD or STD cast1995-05-19 02:03:0056.619 N, 9.01017 WRRS Charles Darwin CD93B
849004CTD or STD cast1995-05-19 03:00:0056.62867 N, 9.02833 WRRS Charles Darwin CD93B
849016CTD or STD cast1995-05-19 04:23:0056.63267 N, 9.07283 WRRS Charles Darwin CD93B
849446CTD or STD cast1995-05-19 05:39:0056.6455 N, 9.11283 WRRS Charles Darwin CD93B
849182CTD or STD cast1995-05-19 07:02:0056.65683 N, 9.15033 WRRS Charles Darwin CD93B
849028CTD or STD cast1995-05-19 08:35:0056.6745 N, 9.19733 WRRS Charles Darwin CD93B
849041CTD or STD cast1995-05-19 10:29:0056.6995 N, 9.32833 WRRS Charles Darwin CD93B
849458CTD or STD cast1995-05-19 12:17:0056.7355 N, 9.40683 WRRS Charles Darwin CD93B
848142CTD or STD cast1995-05-23 20:17:0056.99867 N, 11.00067 WRRS Charles Darwin CD93B
848154CTD or STD cast1995-05-24 01:21:0056.99867 N, 9.9995 WRRS Charles Darwin CD93B
848431CTD or STD cast1995-05-24 02:17:0057.0025 N, 9.99967 WRRS Charles Darwin CD93B
849317CTD or STD cast1995-05-24 09:35:0057.008 N, 10.01833 WRRS Charles Darwin CD93B
848443CTD or STD cast1995-05-24 13:08:0056.73917 N, 9.38967 WRRS Charles Darwin CD93B
848455CTD or STD cast1995-05-24 15:15:0056.74067 N, 9.38917 WRRS Charles Darwin CD93B
849108CTD or STD cast1995-05-25 19:22:0056.73567 N, 9.392 WRRS Charles Darwin CD93B
848559CTD or STD cast1995-05-25 21:10:0056.73367 N, 9.39317 WRRS Charles Darwin CD93B
848560CTD or STD cast1995-05-26 07:16:0056.73383 N, 9.389 WRRS Charles Darwin CD93B
848572CTD or STD cast1995-05-26 09:15:0056.7325 N, 9.396 WRRS Charles Darwin CD93B
849121CTD or STD cast1995-05-26 12:08:0056.733 N, 9.39217 WRRS Charles Darwin CD93B
848584CTD or STD cast1995-05-26 13:30:0056.73467 N, 9.3855 WRRS Charles Darwin CD93B
848234CTD or STD cast1995-05-27 03:14:0056.60433 N, 8.92867 WRRS Charles Darwin CD93B
848246CTD or STD cast1995-05-27 03:55:0056.61733 N, 8.99083 WRRS Charles Darwin CD93B
849145CTD or STD cast1995-05-27 05:02:0056.62867 N, 9.02267 WRRS Charles Darwin CD93B
848258CTD or STD cast1995-05-27 06:10:0056.644 N, 9.10867 WRRS Charles Darwin CD93B
848271CTD or STD cast1995-05-27 07:38:0056.67133 N, 9.199 WRRS Charles Darwin CD93B
849170CTD or STD cast1995-05-27 09:52:0056.698 N, 9.33233 WRRS Charles Darwin CD93B
849157CTD or STD cast1995-05-27 12:04:0056.736 N, 9.395 WRRS Charles Darwin CD93B
390131CTD or STD cast1995-07-25 19:54:0056.6055 N, 8.9387 WRRS Challenger CH120
390143CTD or STD cast1995-07-25 21:57:0056.6167 N, 9.0095 WRRS Challenger CH120
390155CTD or STD cast1995-07-25 23:25:0056.624 N, 9.025 WRRS Challenger CH120
390167CTD or STD cast1995-07-26 01:49:0056.6358 N, 9.0657 WRRS Challenger CH120
390179CTD or STD cast1995-07-26 03:12:0056.6433 N, 9.125 WRRS Challenger CH120
390180CTD or STD cast1995-07-26 06:02:0056.6638 N, 9.1662 WRRS Challenger CH120
390192CTD or STD cast1995-07-26 07:39:0056.681 N, 9.2487 WRRS Challenger CH120
390211CTD or STD cast1995-07-27 00:52:0056.7368 N, 9.449 WRRS Challenger CH120
1287261Water sample data1995-07-27 00:52:0056.7368 N, 9.449 WRRS Challenger CH120
849759CTD or STD cast1995-08-15 21:24:0056.60433 N, 8.93117 WRRS Challenger CH121A
849760CTD or STD cast1995-08-15 23:01:0056.6165 N, 8.99 WRRS Challenger CH121A
849551CTD or STD cast1995-08-15 23:58:0056.628 N, 9.02767 WRRS Challenger CH121A
849772CTD or STD cast1995-08-16 01:03:0056.64233 N, 9.0905 WRRS Challenger CH121A
849784CTD or STD cast1995-08-16 01:58:0056.64517 N, 9.11617 WRRS Challenger CH121A
849563CTD or STD cast1995-08-16 03:15:0056.63633 N, 9.171 WRRS Challenger CH121A
849803CTD or STD cast1995-08-16 12:03:0056.64 N, 8.99517 WRRS Challenger CH121A
849815CTD or STD cast1995-08-16 17:20:0056.61617 N, 9.02267 WRRS Challenger CH121A
851715CTD or STD cast1995-08-22 16:28:0056.6445 N, 9.1115 WRRS Challenger CH121B
1287433Water sample data1995-08-22 16:51:0056.64454 N, 9.11146 WRRS Challenger CH121B
851807CTD or STD cast1995-08-24 02:05:0056.73467 N, 9.40133 WRRS Challenger CH121B
1287562Water sample data1995-08-24 02:40:0056.73468 N, 9.4014 WRRS Challenger CH121B
1288319Water sample data1995-08-24 02:40:0056.73468 N, 9.4014 WRRS Challenger CH121B
850841CTD or STD cast1995-08-24 04:00:0056.7335 N, 9.39833 WRRS Challenger CH121B
851579CTD or STD cast1995-08-24 05:01:0056.70033 N, 9.321 WRRS Challenger CH121B
1287574Water sample data1995-08-24 05:32:0056.70039 N, 9.32098 WRRS Challenger CH121B
850853CTD or STD cast1995-08-24 06:35:0056.70033 N, 9.327 WRRS Challenger CH121B
1287586Water sample data1995-08-24 06:36:0056.70031 N, 9.32702 WRRS Challenger CH121B
850865CTD or STD cast1995-08-24 07:36:0056.66983 N, 9.19083 WRRS Challenger CH121B
1287598Water sample data1995-08-24 08:00:0056.66977 N, 9.1909 WRRS Challenger CH121B
851580CTD or STD cast1995-08-24 09:03:0056.65533 N, 9.1475 WRRS Challenger CH121B
1287605Water sample data1995-08-24 09:30:0056.65538 N, 9.14758 WRRS Challenger CH121B
850877CTD or STD cast1995-08-24 10:48:0056.64383 N, 9.11233 WRRS Challenger CH121B
1287617Water sample data1995-08-24 11:07:0056.64386 N, 9.11238 WRRS Challenger CH121B
850889CTD or STD cast1995-08-24 12:13:0056.63233 N, 9.07133 WRRS Challenger CH121B
1287629Water sample data1995-08-24 12:27:0056.63238 N, 9.07129 WRRS Challenger CH121B
851844CTD or STD cast1995-08-24 13:30:0056.62567 N, 9.0265 WRRS Challenger CH121B
1287630Water sample data1995-08-24 13:42:0056.62568 N, 9.02657 WRRS Challenger CH121B
850890CTD or STD cast1995-08-24 14:41:0056.6185 N, 9.00833 WRRS Challenger CH121B
1287642Water sample data1995-08-24 14:49:0056.61857 N, 9.00831 WRRS Challenger CH121B
850908CTD or STD cast1995-08-24 15:53:0056.61417 N, 8.98433 WRRS Challenger CH121B
1287654Water sample data1995-08-24 15:59:0056.61423 N, 8.9843 WRRS Challenger CH121B
850921CTD or STD cast1995-08-24 16:47:0056.6045 N, 8.931 WRRS Challenger CH121B
1287666Water sample data1995-08-24 16:52:0056.60442 N, 8.93092 WRRS Challenger CH121B
851893CTD or STD cast1995-09-02 14:11:0056.62467 N, 9.02467 WRRS Challenger CH121C
851985CTD or STD cast1995-09-04 07:29:0056.72967 N, 9.43083 WRRS Challenger CH121C
852000CTD or STD cast1995-09-05 02:18:0056.64533 N, 9.11017 WRRS Challenger CH121C
852153CTD or STD cast1995-09-05 03:20:0056.6735 N, 9.19533 WRRS Challenger CH121C
852012CTD or STD cast1995-09-05 08:33:0056.713 N, 9.4275 WRRS Challenger CH121C
852036CTD or STD cast1995-09-06 23:37:0056.60517 N, 8.9305 WRRS Challenger CH121C
852048CTD or STD cast1995-09-07 00:16:0056.6205 N, 9.00917 WRRS Challenger CH121C
852061CTD or STD cast1995-09-07 02:17:0056.62717 N, 9.0255 WRRS Challenger CH121C
852177CTD or STD cast1995-09-07 02:53:0056.63517 N, 9.06667 WRRS Challenger CH121C
854958CTD or STD cast1995-12-07 21:33:0056.6095 N, 8.9215 WRRS Challenger CH123B
855741CTD or STD cast1995-12-07 22:21:0056.62883 N, 8.9755 WRRS Challenger CH123B
855753CTD or STD cast1995-12-07 23:04:0056.63417 N, 9.02267 WRRS Challenger CH123B
854971CTD or STD cast1995-12-08 00:14:0056.63733 N, 9.06717 WRRS Challenger CH123B
855335CTD or STD cast1995-12-08 01:18:0056.646 N, 9.10367 WRRS Challenger CH123B
855347CTD or STD cast1995-12-08 02:31:0056.66133 N, 9.145 WRRS Challenger CH123B
855857CTD or STD cast1995-12-08 04:30:0056.67517 N, 9.18383 WRRS Challenger CH123B
855359CTD or STD cast1995-12-08 06:23:0056.69283 N, 9.24733 WRRS Challenger CH123B
855360CTD or STD cast1995-12-08 08:24:0056.70167 N, 9.325 WRRS Challenger CH123B
855046CTD or STD cast1995-12-08 10:31:0056.7335 N, 9.3995 WRRS Challenger CH123B
855372CTD or STD cast1995-12-08 12:43:0056.7355 N, 9.40367 WRRS Challenger CH123B
855384CTD or STD cast1995-12-08 15:06:0056.733 N, 9.39917 WRRS Challenger CH123B
855058CTD or STD cast1995-12-08 15:26:0056.73767 N, 9.3985 WRRS Challenger CH123B
855396CTD or STD cast1995-12-08 19:19:0056.7395 N, 9.3905 WRRS Challenger CH123B
855869CTD or STD cast1995-12-09 04:21:0056.988 N, 10.9835 WRRS Challenger CH123B
855488CTD or STD cast1995-12-11 04:17:0056.74167 N, 9.3855 WRRS Challenger CH123B
855870CTD or STD cast1995-12-11 06:24:0056.73317 N, 9.3965 WRRS Challenger CH123B
856049CTD or STD cast1996-02-03 17:20:0056.60367 N, 8.9245 WRRS Challenger CH125A
856246CTD or STD cast1996-02-03 18:23:0056.60267 N, 8.937 WRRS Challenger CH125A
856050CTD or STD cast1996-02-03 19:13:0056.62583 N, 8.97917 WRRS Challenger CH125A
856363CTD or STD cast1996-02-03 19:50:0056.61083 N, 9.00817 WRRS Challenger CH125A
856062CTD or STD cast1996-02-03 21:33:0056.62883 N, 9.01 WRRS Challenger CH125A
856375CTD or STD cast1996-02-03 23:30:0056.64 N, 9.05867 WRRS Challenger CH125A
856258CTD or STD cast1996-02-04 00:34:0056.642 N, 9.0795 WRRS Challenger CH125A
856086CTD or STD cast1996-02-04 01:38:0056.64883 N, 9.1105 WRRS Challenger CH125A
856098CTD or STD cast1996-02-04 03:08:0056.66317 N, 9.147 WRRS Challenger CH125A
856271CTD or STD cast1996-02-04 04:48:0056.66733 N, 9.20067 WRRS Challenger CH125A
856283CTD or STD cast1996-02-06 21:27:0056.70783 N, 9.40567 WRRS Challenger CH125A
856129CTD or STD cast1996-02-06 23:31:0056.69533 N, 9.33217 WRRS Challenger CH125A
856387CTD or STD cast1996-02-07 01:03:0056.68417 N, 9.248 WRRS Challenger CH125A
857249CTD or STD cast1996-02-20 11:06:0056.7355 N, 9.4005 WRRS Challenger CH125B
1290489Water sample data1996-02-20 11:36:0056.73547 N, 9.40052 WRRS Challenger CH125B
1700299Water sample data1996-02-20 11:36:0056.73547 N, 9.40052 WRRS Challenger CH125B
1868097Water sample data1996-02-20 11:36:0056.73547 N, 9.40052 WRRS Challenger CH125B
857317CTD or STD cast1996-02-20 13:17:0056.73717 N, 9.39483 WRRS Challenger CH125B
1290490Water sample data1996-02-20 13:22:0056.73723 N, 9.39488 WRRS Challenger CH125B
1700306Water sample data1996-02-20 13:22:0056.73723 N, 9.39488 WRRS Challenger CH125B
1868104Water sample data1996-02-20 13:22:0056.73723 N, 9.39488 WRRS Challenger CH125B
857250CTD or STD cast1996-02-20 14:48:0056.71017 N, 9.36133 WRRS Challenger CH125B
1290508Water sample data1996-02-20 15:23:0056.71024 N, 9.36131 WRRS Challenger CH125B
1700318Water sample data1996-02-20 15:23:0056.71024 N, 9.36131 WRRS Challenger CH125B
1868116Water sample data1996-02-20 15:23:0056.71024 N, 9.36131 WRRS Challenger CH125B
856861CTD or STD cast1996-02-20 16:33:0056.69817 N, 9.32167 WRRS Challenger CH125B
1290521Water sample data1996-02-20 17:02:0056.69809 N, 9.32171 WRRS Challenger CH125B
1700331Water sample data1996-02-20 17:02:0056.69809 N, 9.32171 WRRS Challenger CH125B
1868128Water sample data1996-02-20 17:02:0056.69809 N, 9.32171 WRRS Challenger CH125B
857471CTD or STD cast1996-02-20 18:18:0056.69 N, 9.25383 WRRS Challenger CH125B
1290533Water sample data1996-02-20 18:48:0056.68999 N, 9.25383 WRRS Challenger CH125B
1700343Water sample data1996-02-20 18:48:0056.68999 N, 9.25383 WRRS Challenger CH125B
1868141Water sample data1996-02-20 18:48:0056.68999 N, 9.25383 WRRS Challenger CH125B
856873CTD or STD cast1996-02-20 20:26:0056.67633 N, 9.2525 WRRS Challenger CH125B
1290545Water sample data1996-02-20 20:51:0056.67638 N, 9.25252 WRRS Challenger CH125B
1700355Water sample data1996-02-20 20:51:0056.67638 N, 9.25252 WRRS Challenger CH125B
1868153Water sample data1996-02-20 20:51:0056.67638 N, 9.25252 WRRS Challenger CH125B
856885CTD or STD cast1996-02-20 22:03:0056.668 N, 9.1935 WRRS Challenger CH125B
1290557Water sample data1996-02-20 22:24:0056.66796 N, 9.19345 WRRS Challenger CH125B
1700367Water sample data1996-02-20 22:24:0056.66796 N, 9.19345 WRRS Challenger CH125B
1868165Water sample data1996-02-20 22:24:0056.66796 N, 9.19345 WRRS Challenger CH125B
856897CTD or STD cast1996-02-20 23:18:0056.65483 N, 9.14867 WRRS Challenger CH125B
1290569Water sample data1996-02-20 23:36:0056.65479 N, 9.14866 WRRS Challenger CH125B
1700379Water sample data1996-02-20 23:36:0056.65479 N, 9.14866 WRRS Challenger CH125B
1868177Water sample data1996-02-20 23:36:0056.65479 N, 9.14866 WRRS Challenger CH125B
857483CTD or STD cast1996-02-21 00:27:0056.641 N, 9.11483 WRRS Challenger CH125B
1290570Water sample data1996-02-21 00:49:0056.64092 N, 9.1149 WRRS Challenger CH125B
1700380Water sample data1996-02-21 00:49:0056.64092 N, 9.1149 WRRS Challenger CH125B
1868189Water sample data1996-02-21 00:49:0056.64092 N, 9.1149 WRRS Challenger CH125B
856904CTD or STD cast1996-02-21 01:47:0056.63967 N, 9.08717 WRRS Challenger CH125B
1290582Water sample data1996-02-21 02:05:0056.63969 N, 9.08712 WRRS Challenger CH125B
1700392Water sample data1996-02-21 02:05:0056.63969 N, 9.08712 WRRS Challenger CH125B
1868190Water sample data1996-02-21 02:05:0056.63969 N, 9.08712 WRRS Challenger CH125B
856916CTD or STD cast1996-02-21 03:08:0056.63183 N, 9.06633 WRRS Challenger CH125B
1290594Water sample data1996-02-21 03:21:0056.63184 N, 9.06635 WRRS Challenger CH125B
1700411Water sample data1996-02-21 03:21:0056.63184 N, 9.06635 WRRS Challenger CH125B
1868208Water sample data1996-02-21 03:21:0056.63184 N, 9.06635 WRRS Challenger CH125B
857643CTD or STD cast1996-02-21 05:21:0056.625 N, 9.01483 WRRS Challenger CH125B
1290613Water sample data1996-02-21 05:36:0056.62507 N, 9.01478 WRRS Challenger CH125B
1700435Water sample data1996-02-21 05:36:0056.62507 N, 9.01478 WRRS Challenger CH125B
1868233Water sample data1996-02-21 05:36:0056.62507 N, 9.01478 WRRS Challenger CH125B
857655CTD or STD cast1996-02-21 20:47:0056.61933 N, 9.00983 WRRS Challenger CH125B
1290625Water sample data1996-02-21 20:56:0056.6193 N, 9.00979 WRRS Challenger CH125B
1700447Water sample data1996-02-21 20:56:0056.6193 N, 9.00979 WRRS Challenger CH125B
1868245Water sample data1996-02-21 20:56:0056.6193 N, 9.00979 WRRS Challenger CH125B
857495CTD or STD cast1996-02-21 22:09:0056.60283 N, 8.93167 WRRS Challenger CH125B
1289544Water sample data1996-02-21 22:16:0056.60284 N, 8.93166 WRRS Challenger CH125B
1699217Water sample data1996-02-21 22:16:0056.60284 N, 8.93166 WRRS Challenger CH125B
1866853Water sample data1996-02-21 22:16:0056.60284 N, 8.93166 WRRS Challenger CH125B
858100CTD or STD cast1996-04-21 21:15:0056.71883 N, 9.40517 WRRS Challenger CH126A
1675645Water sample data1996-04-21 22:12:0056.7188 N, 9.40511 WRRS Challenger CH126A
858394CTD or STD cast1996-04-22 01:52:0056.688 N, 9.181 WRRS Challenger CH126A
1675669Water sample data1996-04-22 02:27:0056.68806 N, 9.18103 WRRS Challenger CH126A
858112CTD or STD cast1996-04-22 04:24:0056.6555 N, 9.10817 WRRS Challenger CH126A
1675670Water sample data1996-04-22 04:54:0056.65556 N, 9.1082 WRRS Challenger CH126A
858124CTD or STD cast1996-04-22 09:21:0056.71767 N, 9.41033 WRRS Challenger CH126A
1675682Water sample data1996-04-22 10:17:0056.71763 N, 9.41033 WRRS Challenger CH126A
858289CTD or STD cast1996-04-22 22:58:0056.61733 N, 8.9355 WRRS Challenger CH126A
1675694Water sample data1996-04-22 23:06:0056.6173 N, 8.93558 WRRS Challenger CH126A
858136CTD or STD cast1996-04-23 00:15:0056.61533 N, 9.00633 WRRS Challenger CH126A
1675701Water sample data1996-04-23 00:25:0056.6154 N, 9.00633 WRRS Challenger CH126A
858401CTD or STD cast1996-04-23 01:10:0056.61367 N, 9.02317 WRRS Challenger CH126A
1675713Water sample data1996-04-23 01:23:0056.61373 N, 9.02321 WRRS Challenger CH126A
858437CTD or STD cast1996-04-23 02:15:0056.61883 N, 9.08567 WRRS Challenger CH126A
1675725Water sample data1996-04-23 02:36:0056.61887 N, 9.08571 WRRS Challenger CH126A
858148CTD or STD cast1996-04-23 09:14:0056.597 N, 8.93867 WRRS Challenger CH126A
1675737Water sample data1996-04-23 09:21:0056.59705 N, 8.93874 WRRS Challenger CH126A
858290CTD or STD cast1996-04-23 11:19:0056.59567 N, 8.91367 WRRS Challenger CH126A
1675749Water sample data1996-04-23 11:26:0056.59571 N, 8.9136 WRRS Challenger CH126A
858413CTD or STD cast1996-04-23 19:09:0056.63217 N, 9.028 WRRS Challenger CH126A
1675750Water sample data1996-04-23 19:24:0056.63211 N, 9.02807 WRRS Challenger CH126A
858806CTD or STD cast1996-05-02 07:30:0056.7375 N, 9.39083 WRRS Challenger CH126B
859674CTD or STD cast1996-05-02 10:02:0056.7335 N, 9.401 WRRS Challenger CH126B
859686CTD or STD cast1996-05-02 15:29:0056.74167 N, 9.38617 WRRS Challenger CH126B
858818CTD or STD cast1996-05-02 17:52:0056.73533 N, 9.39717 WRRS Challenger CH126B
859698CTD or STD cast1996-05-02 19:49:0056.7365 N, 9.3855 WRRS Challenger CH126B
859705CTD or STD cast1996-05-02 22:35:0056.74633 N, 9.38867 WRRS Challenger CH126B
858449CTD or STD cast1996-05-03 00:29:0056.73283 N, 9.39567 WRRS Challenger CH126B
859717CTD or STD cast1996-05-03 02:02:0056.73367 N, 9.39617 WRRS Challenger CH126B
859729CTD or STD cast1996-05-03 03:40:0056.7335 N, 9.39267 WRRS Challenger CH126B
858450CTD or STD cast1996-05-03 04:20:0056.73383 N, 9.398 WRRS Challenger CH126B
859730CTD or STD cast1996-05-03 06:05:0056.73683 N, 9.3945 WRRS Challenger CH126B
859742CTD or STD cast1996-05-03 08:31:0056.70283 N, 9.321 WRRS Challenger CH126B
859754CTD or STD cast1996-05-03 11:09:0056.67183 N, 9.19883 WRRS Challenger CH126B
858462CTD or STD cast1996-05-03 12:47:0056.6775 N, 9.19433 WRRS Challenger CH126B
859766CTD or STD cast1996-05-03 13:28:0056.6615 N, 9.14033 WRRS Challenger CH126B
859778CTD or STD cast1996-05-03 17:27:0056.653 N, 9.112 WRRS Challenger CH126B
858474CTD or STD cast1996-05-03 18:53:0056.63683 N, 9.06733 WRRS Challenger CH126B
859791CTD or STD cast1996-05-03 20:06:0056.63583 N, 9.02717 WRRS Challenger CH126B
859809CTD or STD cast1996-05-03 21:23:0056.61267 N, 8.99117 WRRS Challenger CH126B
858486CTD or STD cast1996-05-03 22:11:0056.608 N, 8.97767 WRRS Challenger CH126B
859810CTD or STD cast1996-05-03 23:28:0056.61433 N, 8.9365 WRRS Challenger CH126B
859336CTD or STD cast1996-05-08 21:48:0057.001 N, 10.0 WRRS Challenger CH126B
859348CTD or STD cast1996-05-09 04:26:0056.99783 N, 9.999 WRRS Challenger CH126B
858831CTD or STD cast1996-05-09 08:32:0056.99117 N, 10.0035 WRRS Challenger CH126B
858843CTD or STD cast1996-05-09 14:02:0056.636 N, 9.02717 WRRS Challenger CH126B
860571CTD or STD cast1996-07-11 16:04:0056.6315 N, 9.00917 WRRS Challenger CH128A
1292331Water sample data1996-07-11 16:21:0056.63151 N, 9.00916 WRRS Challenger CH128A
860896CTD or STD cast1996-07-20 23:16:0056.67783 N, 9.19067 WRRS Challenger CH128A
1292515Water sample data1996-07-20 23:49:0056.67783 N, 9.19072 WRRS Challenger CH128A
860903CTD or STD cast1996-07-21 02:14:0056.73483 N, 9.39583 WRRS Challenger CH128A
860294CTD or STD cast1996-07-21 03:15:0056.7345 N, 9.3905 WRRS Challenger CH128A
1292527Water sample data1996-07-21 04:06:0056.73447 N, 9.39044 WRRS Challenger CH128A
1292539Water sample data1996-07-21 07:19:0056.66285 N, 9.14221 WRRS Challenger CH128A
860491CTD or STD cast1996-07-21 09:03:0056.64817 N, 9.11133 WRRS Challenger CH128A
1292540Water sample data1996-07-21 09:21:0056.64815 N, 9.1113 WRRS Challenger CH128A
860927CTD or STD cast1996-07-21 10:41:0056.635 N, 9.07233 WRRS Challenger CH128A
1292564Water sample data1996-07-21 10:58:0056.63494 N, 9.07228 WRRS Challenger CH128A
860301CTD or STD cast1996-07-21 12:33:0056.61867 N, 9.0265 WRRS Challenger CH128A
1292576Water sample data1996-07-21 12:47:0056.61861 N, 9.02645 WRRS Challenger CH128A
860939CTD or STD cast1996-07-21 14:49:0056.61667 N, 9.013 WRRS Challenger CH128A
1292588Water sample data1996-07-21 15:01:0056.61663 N, 9.01293 WRRS Challenger CH128A
860509CTD or STD cast1996-07-21 16:28:0056.588 N, 8.95417 WRRS Challenger CH128A
1292607Water sample data1996-07-21 16:36:0056.58792 N, 8.95419 WRRS Challenger CH128A
861389CTD or STD cast1996-08-02 03:10:0056.71433 N, 9.43783 WRRS Challenger CH128B
861390CTD or STD cast1996-08-02 04:48:0056.711 N, 9.454 WRRS Challenger CH128B
861200CTD or STD cast1996-08-02 06:20:0056.71433 N, 9.47583 WRRS Challenger CH128B
861408CTD or STD cast1996-08-02 10:18:0056.7155 N, 9.40433 WRRS Challenger CH128B
861212CTD or STD cast1996-08-02 17:26:0056.67117 N, 9.2005 WRRS Challenger CH128B
861433CTD or STD cast1996-08-03 01:00:0056.64967 N, 9.1245 WRRS Challenger CH128B
861445CTD or STD cast1996-08-03 02:14:0056.63517 N, 9.07283 WRRS Challenger CH128B
861224CTD or STD cast1996-08-03 03:13:0056.62683 N, 9.01983 WRRS Challenger CH128B
861457CTD or STD cast1996-08-03 03:57:0056.6225 N, 9.00267 WRRS Challenger CH128B
861469CTD or STD cast1996-08-03 04:44:0056.61317 N, 8.93683 WRRS Challenger CH128B
861236CTD or STD cast1996-08-05 19:00:0056.99883 N, 9.99633 WRRS Challenger CH128B
861482CTD or STD cast1996-08-05 21:13:0056.99767 N, 9.99583 WRRS Challenger CH128B
861120CTD or STD cast1996-08-05 23:01:0056.99667 N, 10.00467 WRRS Challenger CH128B