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Metadata Report for BODC Series Reference Number 1840371


Metadata Summary

Data Description

Data Category Hydrography time series at depth
Instrument Type
NameCategories
Sea-Bird SBE 37 MicroCat SM-CT with optional pressure (submersible) CTD sensor series  water temperature sensor; salinity sensor
Instrument Mounting subsurface mooring
Originating Country United Kingdom
Originator Mr Povl Abrahamsen
Originating Organization British Antarctic Survey
Processing Status banked
Online delivery of data Download available - Ocean Data View (ODV) format
Project(s) BAS Long Term Monitoring and Survey
 

Data Identifiers

Originator's Identifier OP6_1315_1_SBE37_8267_2321M
BODC Series Reference 1840371
 

Time Co-ordinates(UT)

Start Time (yyyy-mm-dd hh:mm) 2013-03-30 19:15
End Time (yyyy-mm-dd hh:mm) 2015-03-21 10:59
Nominal Cycle Interval 900.0 seconds
 

Spatial Co-ordinates

Latitude 60.56278 S ( 60° 33.8' S )
Longitude 41.63393 W ( 41° 38.0' W )
Positional Uncertainty 0.0 to 0.01 n.miles
Minimum Sensor or Sampling Depth 2321.0 m
Maximum Sensor or Sampling Depth 2321.0 m
Minimum Sensor or Sampling Height 19.0 m
Maximum Sensor or Sampling Height 19.0 m
Sea Floor Depth 2340.0 m
Sea Floor Depth Source DATAHEAD
Sensor or Sampling Distribution Fixed common depth - All sensors are grouped effectively at the same depth which is effectively fixed for the duration of the series
Sensor or Sampling Depth Datum Approximate - Depth is only approximate
Sea Floor Depth Datum Instantaneous - Depth measured below water line or instantaneous water body surface
 

Parameters

BODC CODERankUnitsTitle
AADYAA011DaysDate (time from 00:00 01/01/1760 to 00:00 UT on day)
AAFDZZ011DaysTime (time between 00:00 UT and timestamp)
ACYCAA011DimensionlessSequence number
CNDCPR011Siemens per metreElectrical conductivity of the water body by in-situ conductivity cell
TEMPPR011Degrees CelsiusTemperature of the water body

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 supplied by Natural Environment Research Council (NERC)

You must always use the following attribution statement to acknowledge the source of the information: "Contains data supplied by Natural Environment Research Council."


Narrative Documents

Sea-Bird SBE 37-SM MicroCAT

The SBE 37-SM MicroCAT is a high accuracy conductivity and temperature recorder (pressure optional). Designed for moorings and other long-duration, fixed-site deployments, MicroCATs have non-corroding titanium housings rated for operation to 7000 metres or pressure sensor full scale-range. Communication with the MicroCAT is over an internal, 3-wire, RS-232C link. The MicroCAT's aged and pressure-protected thermistor has a long history of exceptional accuracy and stability (typical drift is less than 0.002° per year). Electrical isolation of the conductivity electronics eliminates any possibility of ground-loop noise.

Specifications

  Temperature
(°C)
Conductivity (S m-1) Optional Pressure
Measurement Range -5 to +35 0 to 7 (0 to 70 mS cm-1) 0 to full scale range: 20 / 100 / 350 / 1000 / 2000 / 3500 / 7000 metres
Initial accuracy 0.002 0.0003 0.1% of full scale range
Typical Stability 0.0002 per month 0.0003 per month 0.05% of full scale range per year
Resolution 0.0001 0.00001 0.002% of full scale range
Sensor Calibration +1 to +32 0 to 6; physical calibration over range 2.6 to 6 S m-1, plus zero conductivity (air) Ambient pressure to full scale range in 5 steps
Memory 8 Mbyte non-volatile FLASH memory
Data Storage Converted temperature and conductivity: 6 bytes per sample (3 bytes each)
Time: 4 bytes per sample
Pressure (optional): 5 bytes per sample
Real-Time Clock 32,768 Hz TCXO accurate to ±1 minutes year-1
Standard Internal Batteries Nominal 10.6 Ampere-hour pack consisting of 12 AA lithium batteries. Provides sufficient capacity for more than 630,000 samples for a typical sampling scheme
Housing Titanium pressure case rated at 7000 metres
Weight (without pressure) In water: 2.3 kg
In air: 3.8 kg

Further information can be found via the following link: SBE 37-SM MicroCAT Datasheet

BODC Data Processing

Data Processing

The data arrived at BODC as individual .mat files containing data collected on moorings OP1, OP2, OP3, OP4, OP5, OP6, OP7, CI1 and CI2. They were submitted as part of an accession which includes data from several mooring instruments e.g. Aquadopp, RCM8, RCM11, RBR, SBE37 and SBE39.

Reformatting

Parameters in the originator's files were reformatted into an internal file format using BODC standard procedures.

The following table lists all the parameters included in the internal format files, showing how the originator's variables as named in the matlab files were mapped to appropriate BODC parameter codes.

Originator's Variable Originator's Units BODC Parameter Code BODC Units Comments
temp C TEMPPR01 C

 

cond mS cm-1 CNDCPR01 S m-1 Conversion by multiplying by 0.1
    2007 - 2015 only    
press dbar PREXMCAT dbar Used for SBE37 data
press dbar PRESPS01 dbar Used for SBE39 data
    2015 - 2017 only    
press dbar PREXPR01 dbar Used for both SBE39 and SBE37 data
press_inferred dbar PREXSINT dbar Used for both SBE39 and SBE37 data where pressure was inferred from a neighbouring instrument
    2017 - 2019 only    
press dbar PREXPR01 dbar Used for both SBE39 and SBE37 data where a pressure sensor was available on the intrument

No derived parameters were calculated by BODC. Please note that not all parameters are present in all files.

Screening

Quality control flags were automatically added to data outside the expected parameter specific range during the reformatting process. All parameters were then visualised and screened using in house software, and any improbable or missing data point was assigned a quality control flag.

Originator's Data processing

Sampling strategy

Sampling was carried out as part of the BAS LTMS (British Antarctic Survey Long Term Monitoring and Survey) until 2016. From 2016 onwards the moorings are split between 'The Ocean Regulation of Climate by Heat and Carbon Sequestration and Transports (ORCHESTRA)' project and 'Dynamics of the Orkney Passage Outflow (DynOPO)' project.

The projects involve the deployment of moorings CI1, CI2, OP1, OP2, OP3, OP4, OP5, OP6 and OP7 in the Southern Ocean, situated north of Coronation Island and the Orkney Passage in the Weddell and Scotia Sea.

Moorings CI1 and CI2 were deployed from 2005 to 2007 and moorings OP1, OP2, OP3, OP4, OP5 and OP6 have been continuously maintained since 2007 with the addition of OP7 in 2015.

SBE 37 and SBE39 instruments were deployed on the moorings. Data have been collected at variable intervals: 5 minutes interval on the Coronation Island moorings, 7.5 minute interval on the instruments deployed on OP2 and OP3 in 2007 and 15 minute intervals since then. Gaps in the series may be caused by either instruments not being recovered, or data not being collected due to instrument malfunction.

Data processing

Little information is known with regards to the exact details of the calibrations carried out on the mooring data. Data processing, visualisation and calibration were carried out through the use of scripts for Matlab version R2014b produced and ran by the originator.

An offset has been applied some of the channels. The values for each deployment/instrument/channel combination are shown in the table below:

Mooring Time period (UT) Depth (m) Serial Number Offset Applied Channel
2009 - 2011 Deployment
OP3 2009-03-02 - 2011-02-25 1516 2956 0.-0.0036 Conductivity
2011 - 2013 Deployment
OP1 2011-03-26 - 2013-04-01 2170 7386 0.0136 Conductivity
OP1 2011-03-26 - 2013-04-01 2944 7385 0.0157 Conductivity
OP1 2011-03-26 - 2013-04-01 3633 7387 0.0121 Conductivity
OP2 2011-03-27 - 2013-03-31 1450 2707 0.0036 Conductivity
OP2 2011-03-27 - 2013-03-31 1594 2956 0.0071 Conductivity
OP2 2011-03-27 - 2013-03-31 1733 7384 0.0107 Conductivity
OP2 2011-03-27 - 2013-03-31 3090 7380 0.0079 Conductivity
OP4 2011-03-27 - 2013-03-03 2201 7383 0.0036 Conductivity
OP4 2011-03-27 - 2013-03-03 2935 7382 0.0086 Conductivity
OP6 2012-04-01 - 2013-03-30 2290 8267 0.0093 Conductivity
2013 - 2015 Deployment
OP1 2013-04-02 - 2015-03-20 2144 7386

-6.0*10-4

-0.0018

Temperature

Conductivity

OP1 2013-04-02 - 2015-03-20 2917 7387

-4.0*10-4

0.0081

Temperature

Conductivity

OP1 2013-04-02 - 2015-03-20 3605 7385 0.0091 Conductivity
OP2 2013-04-01 - 2015-03-20 1510 2956

-0.0019

-0.0051

Temperature

Conductivity

OP2 2013-04-01 - 2015-03-20 2269 7381

4.0*10-4

0.0018

Temperature

Conductivity

OP2 2013-04-01 - 2015-03-20 3002 7380

9.0*10-4

0.0032

Temperature

Conductivity

OP3 2013-04-01 - 2015-03-20 1450 2707

9.0*10-4

1.4*10-4

Temperature

Conductivity

OP4 2013-04-03 - 2015-03-21 2196 7382

-0.50

0.0011

0.0041

Pressure

Temperature

Conductivity

OP4 2013-04-03 - 2015-03-21 2930 7383

9.0*10-4

0.0024

Temperature

Conductivity

OP6 2013-03-30 - 2015-03-21 2321 8267

0.0011

0.0154

Temperature

Conductivity

2015 - 2017 Deployment
OP1 2015-04-02 - 2017-04-05 3590 7316

0.8

0.0017

0.0003

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 3510 7297

-1

0.0035

0.0004

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 4310 7314

0.3

-0.0028

0.0009

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 3310 7299

-0.0003

0.0004

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 3210 7294

0.1

0.0005

0.0004

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 3110 7311

-0.7

-0.005

0.0004

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 3010 8076

0.4

-0.0045

0.0016

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 2910 7310

-0.0035

0.0002

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 2810 7302

-0.3

-0.0017

0.0014

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 2610 9379

-0.2

0.001

0.0061

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 2509 7307

-0.4

-0.0015

-0.0003

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 2260 7313

-3.8

-0.0033

0.0006

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 2110 9394

-1.5

-0.0031

0.0005

Pressure

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 1960 7309

0.0007

-0.0002

Conductivity

Temperature

OP1 2015-04-02 - 2017-04-05 1810 7308

-0.2

0.0013

-0.0009

Pressure

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 2991 7288

-0.5

-0.0058

0.0002

Pressure

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 2808 7290

-0.0017

0.0002

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 2708 7291

-0.5

-0.0025

0.0002

Pressure

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 2608 7289

-0.5

-0.0005

0.0002

Pressure

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 2408 7292

0.5

-0.0036

-0.0001

Pressure

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 2258 7293

-0.0038

0.0001

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 2108 7295

0.5

-0.0006

0.0006

Pressure

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 1958 8075

-0.0045

0.0006

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 1808 7303

0.1

0.015

0.0001

Pressure

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 1658 7382

0.003

0.0016

Conductivity

Temperature

OP2 2015-04-04 - 2017-04-14 1508 7387

0.004

0.0002

Conductivity

Temperature

OP3 2015-04-03 - 2017-04-15 1230 4897 15.2261 Pressure
OP3 2015-04-02 - 2017-04-03 1722 7386

-0.003

0.0001

Conductivity

Temperature

OP3 2015-04-02 - 2017-04-03 1439 7383

0.0026

0.0015

Conductivity

Temperature

OP4 2015-04-02 - 2017-04-07 2931 2956

9

-0.0056

-0.0012

Pressure

Conductivity

Temperature

OP4 2015-04-02 - 2017-04-07 1838 2707

-1

-0.0018

-0.0003

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 3377 12458

-1.6

0.0005

0.001

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 3297 12456

-1.2

0.0005

0.0015

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 3197 12455

-0.4

0.0005

0.0006

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 3097 12464

-0.7

0.0005

0.0011

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 2947 12469

-1.4

0.0005

0.0009

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 2797 12476

-1.5

0.0005

0.0007

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 2647 12475

-0.9

0.0005

0.0015

Pressure

Conductivity

Temperature

OP5 2015-04-02 - 2017-04-06 2497 12473

-0.9

0.0005

0.0015

Pressure

Conductivity

Temperature

OP6 2015-04-02 - 2017-04-06 2319 8267

0.012

0.001

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 3016 7298

0.2

0.0024

0.0002

Pressure

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 2836 12462

-1.7

-0.0008

0.0012

Pressure

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 2736 7385

0.0025

0.0004

Pressure

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 2636 7312

-0.2

0.0008

0.0008

Pressure

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 2436 7304

-0.4

-0.0005

0.0008

Pressure

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 2286 7381

0.003

0.0009

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 2136 7305

-0.3

0.0032

0.0009

Pressure

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 1986 7306

0.0053

0.0008

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 1836 7315

0.5928

0.0045

0.0012

Pressure

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 1686 7380

0.0045

0.0013

Conductivity

Temperature

OP7 2015-04-02 - 2017-04-09 1536 12463

-1

-0.0015

0.0012

Pressure

Conductivity

Temperature

2017 - 2019 Deployment
OP1 2017-04-18 - 2019-01-29 3674 7382

0

0.0033

0.0011

Pressure

Conductivity

Temperature

OP1 2017-04-18 - 2019-01-29 2984 7381

0

1.0*10-3

4.0*10-4

Pressure

Conductivity

Temperature

OP1 2017-04-18 - 2019-01-29 2630 4413 - -
OP1 2017-04-18 - 2019-01-29 2211 7380

0

0.0028

8.0*10-4

Pressure

Conductivity

Temperature

OP1 2017-04-18 - 2019-01-29 1877 4409 - -
OP2 2017-04-18 - 2019-01-27 3037 7386

0

-0.0058

-3.0*10-4

Pressure

Conductivity

Temperature

OP2 2017-04-18 - 2019-01-27 2333 7385

0

-7.0*10-4

0

Pressure

Conductivity

Temperature

OP2 2017-04-18 - 2019-01-27 1937 0083 - -
OP2 2017-04-18 - 2019-01-27 1538 7383

0

0.0030

0.0012

Pressure

Conductivity

Temperature

OP3 2017-04-19 - 2019-01-29 1718 8541

1

0.0022

4.0*10-4

Pressure

Conductivity

Temperature

OP3 2017-04-19 - 2019-01-29 1718 8540

1

7.0*10-4

4.0*10-4

Pressure

Conductivity

Temperature

OP4 2017-04-21 - 2019-01-29 2930 2678

-1.5

5.0*10-4

4.0*10-4

Pressure

Conductivity

Temperature

OP4 2017-04-21 - 2019-01-29 2200 4713 - -
OP4 2017-04-21 - 2019-01-29 1842 4418 - -
OP5 2017-04-19 - 2019-01-29 3369 7387

0

0.0022

-3.0*10-4

Pressure

Conductivity

Temperature

OP5 2017-04-19 - 2019-01-29 2988 4716 - -
OP6 2017-04-20 - 2019-01-30 2292 8267

-1.0*10-3

1.0*10-3

Conductivity

Temperature

Several instruments deployed in the 2013/15 period show evidence of knock-down but the data colleaction seems to be unnafected. According to the originator some of the moorings were deployed with insufficient buyoancy which caused the knockdowns. These instances are especially visible on moorings OP1 and OP2, Series Reference number 1840205, 1840229, 1840254, 1840266 and 1840278

Several instruments deployed in the 2015/17 period did not have a pressure sensor and used inferred pressure calculated from the closest neigbhouring pressure sensor. This includes five SBE39 instruments (s/n 4413, 4716, 4713, 4418 and 4409) and one SBE37 instrument (s/n 8267).

Several instruments deployed in the 2017/19 period did not have a pressure sensor, therefore no pressure channel was transferred with the data and only a nominal depth is used in the metadata. This includes all SBE39 instruments (s/n 4413, 4409, 0083, 4713, 4418 and 4716) and one SBE37 instrument (s/n 8267).


Project Information

BAS Long Term Monitoring and Survey

Introduction

The Long Term Monitoring and Survey project (LTMS) has been running since the British Antarctic Survey (BAS) was created. This project is one of the BAS core projects, with several groups of scientists collecting various types of data e.g biological, geological, atmospheric, among others.

Data collection is achievable through a wide scope of instruments and platforms, e.g. the Antarctic research stations, autonomous instrument platforms deployed on or from BAS research ships, BAS aircrafts, satellite remote sensing and others.

Scientific Objectives

This project was implemented in order to measure change and variability in the Earth system. Its long term duration allows for the monitoring of processes that could be missed in shorter term studies and experiments. The data collected is also used to check and improve the reliability of models used to stimulate and predict the behavior of the Earth system.

The main objectives are:

  • Topographic survey
  • Geosciences survey
  • Biological survey and monitoring
  • Atmospheric and oceanographic monitoring

Data Availability

The data sets obtained through this project are available to the academic community.


Data Activity or Cruise Information

Data Activity

Start Date (yyyy-mm-dd) 2013-03-30
End Date (yyyy-mm-dd) 2015-03-23
Organization Undertaking ActivityBritish Antarctic Survey
Country of OrganizationUnited Kingdom
Originator's Data Activity IdentifierOP6
Platform Categorysubsurface mooring

Orkney Passage mooring 6 (OP6)

The mooring was deployed at the following positions:

Organisation Undertaking Activity British Antarctic Survey, Cambridge
Country of Organisation United Kingdom
Originator's Data Activity Identifier OP6
Platform Category Subsurface mooring
Latitude (+ve N) -60.5629
Longitude (+ve E) -41.6327
Water Depth (m) 2309

The mooring was deployed on the Orkney Passage on cruise JR20130317 (JR252B, JR272B, JR273A, JR281, UKD-4) on 30 March 2013 and recovery was done on cruise JR20150309 (JR272D, JR310) on 21 March 2015.

The table below lists the instruments deployed on this mooring:

Instrument type Serial Number Data start (UT) Data end (UT) Instrument depth (m)
Aquadopp 9250 2013-03-30 16:30:00 2015-03-23 16:59:35 2041
Aquadopp 9264 2013-03-30 16:30:00 2015-03-23 16:43:52 2297
Sea Bird SBE37 8267 2013-03-30 17:30:01 2015-03-23 14:07:07 2321

Related Data Activity activities are detailed in Appendix 1

Cruise

Cruise Name JR20130317 (JR252B, JR272B, JR273A, JR281, UKD-4)
Departure Date 2013-03-17
Arrival Date 2013-04-27
Principal Scientist(s)Jean-Baptiste Sallee (British Antarctic Survey)
Ship RRS James Clark Ross

Complete Cruise Metadata Report is available here


Fixed Station Information

Fixed Station Information

Station NameOrkney Passage OP6
CategoryOffshore location
Latitude60° 33.74' S
Longitude41° 37.93' W
Water depth below MSL2309.0 m

Orkney Passage OP6 site

Site OP6 is part of the Orkney Passage mooring array which is an activity covered by the Long Term Monitoring and Survey British Antarctic Survey's (BAS) programme. The data collection is the result of an ongoing collaboration between BAS and the Lamont-Doherty Earth Observatory (LDEO).

This site has been occupied since 2012, the recovery/deployment history, including position details, is presented below:

Deployed Recovered
Year Cruise Year Cruise Latitude (+veN) Longitude (+ve E) Water Depth (m)
2012 JR20120326 (JR254E, JR257, JR272A) 2013 JR20130317 (JR272B, JR273A, JR281, UKD-4) -60.5623 -41.6322 2309
2013 JR20130317 (JR272B, JR273A, JR281, UKD-4) 2015 JR20150309 (JR272D, JR310) -60.5629 -41.6327 2309
2015 JR20150309 (JR272D, JR310) 2017 JR16005 -60.5621 -41.6339 2338

Detailed information for each deployment can be accessed from the OP6 Data Activity document.

Related Fixed Station activities are detailed in Appendix 2


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: OP6

Related series for this Data Activity 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
1840948Currents -subsurface Eulerian2013-03-30 19:15:0060.56278 S, 41.63393 WRRS James Clark Ross JR20130317 (JR252B, JR272B, JR273A, JR281, UKD-4)
1840936Currents -subsurface Eulerian2013-03-30 19:15:1660.56278 S, 41.63393 WRRS James Clark Ross JR20130317 (JR252B, JR272B, JR273A, JR281, UKD-4)

Appendix 2: Orkney Passage OP6

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
1362834Currents -subsurface Eulerian2012-04-02 20:15:0060.56315 S, 41.63217 WRRS James Clark Ross JR20120327 (JR254E, JR257, JR272A)
1362846Currents -subsurface Eulerian2012-04-02 20:15:0060.56315 S, 41.63217 WRRS James Clark Ross JR20120327 (JR254E, JR257, JR272A)
1223533Hydrography time series at depth2012-04-02 20:15:0060.56315 S, 41.63217 WRRS James Clark Ross JR20120327 (JR254E, JR257, JR272A)
1840948Currents -subsurface Eulerian2013-03-30 19:15:0060.56278 S, 41.63393 WRRS James Clark Ross JR20130317 (JR252B, JR272B, JR273A, JR281, UKD-4)
1840936Currents -subsurface Eulerian2013-03-30 19:15:1660.56278 S, 41.63393 WRRS James Clark Ross JR20130317 (JR252B, JR272B, JR273A, JR281, UKD-4)
1814106CTD or STD cast2015-03-21 06:42:0860.5711 S, 41.6281 WRRS James Clark Ross JR20150309 (JR272D, JR310)
1805766Currents -subsurface Eulerian2015-03-21 06:42:3160.57106 S, 41.6281 WRRS James Clark Ross JR20150309 (JR272D, JR310)
1814616CTD or STD cast2015-04-06 09:52:4760.5624 S, 41.633 WRRS James Clark Ross JR20150309 (JR272D, JR310)
1806272Currents -subsurface Eulerian2015-04-06 09:53:0260.56171 S, 41.63373 WRRS James Clark Ross JR20150309 (JR272D, JR310)
1894762Currents -subsurface Eulerian2015-04-06 13:40:0060.56212 S, 41.63388 WRRS James Clark Ross JR20150309 (JR272D, JR310)
1894774Currents -subsurface Eulerian2015-04-06 13:40:0060.56212 S, 41.63388 WRRS James Clark Ross JR20150309 (JR272D, JR310)
1881272Hydrography time series at depth2015-04-06 13:40:0160.56212 S, 41.63388 WRRS James Clark Ross JR20150309 (JR272D, JR310)
2022408Currents -subsurface Eulerian2017-04-20 14:40:0060.56277 S, 41.63182 WRRS James Clark Ross JR16005
2022421Currents -subsurface Eulerian2017-04-20 14:40:0060.56277 S, 41.63182 WRRS James Clark Ross JR16005
2022549Hydrography time series at depth2017-04-20 14:40:0160.56277 S, 41.63182 WRRS James Clark Ross JR16005