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Metadata Report for BODC Series Reference Number 1918815

Metadata Summary

Data Description
Data Category CTD or STD cast
Instrument Type
NameCategories
Sea-Bird SBE 43 Dissolved Oxygen Sensor  dissolved gas sensors
Sea-Bird SBE 911plus CTD  CTD; water temperature sensor; salinity sensor
Tritech PA-200 Altimeter  altimeters
WET Labs {Sea-Bird WETLabs} C-Star transmissometer  transmissometers
Sea-Bird SBE 3plus (SBE 3P) temperature sensor  water temperature sensor
Sea-Bird SBE 4C conductivity sensor  salinity sensor
Chelsea Technologies Group Aquatracka III fluorometer  fluorometers
Biospherical Instruments QCP-2350 [underwater] PAR sensor  radiometers
Instrument Mounting lowered unmanned submersible
Originating Country United Kingdom
Originator Miss Emily Venables
Originating Organization Scottish Association for Marine Science
Processing Status banked
Online delivery of data Download available - Ocean Data View (ODV) format
Project(s) Changing Arctic Ocean
 

Data Identifiers

Originator's Identifier JR17006_053_FINAL_1DB_DOWN
BODC Series Reference 1918815
 

Time Co-ordinates(UT)
Start Time (yyyy-mm-dd hh:mm) 2018-06-28 13:07
End Time (yyyy-mm-dd hh:mm) -
Nominal Cycle Interval 1.0 decibars
 

Spatial Co-ordinates

Latitude 76.61660 N ( 76° 37.0' N )
Longitude 30.00010 E ( 30° 0.0' E )
Positional Uncertainty 0.0 to 0.01 n.miles
Minimum Sensor or Sampling Depth 4.11 m
Maximum Sensor or Sampling Depth 274.21 m
Minimum Sensor or Sampling Height 15.54 m
Maximum Sensor or Sampling Height 285.64 m
Sea Floor Depth 289.75 m
Sea Floor Depth Source GEBCO1401
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 Chart reference - Depth extracted from available chart
 

Parameters
BODC CODERankUnitsTitle
ACYCAA011DimensionlessSequence number
AHSFZZ011MetresHeight (spatial coordinate) relative to bed surface in the water body
ATTNMR011per metreAttenuation (red light wavelength) per unit length of the water body by 20 or 25cm path length transmissometer
CNDCST011Siemens per metreElectrical conductivity of the water body by CTD
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
DOXYSU011Micromoles per litreConcentration of oxygen {O2 CAS 7782-44-7} per unit volume of the water body [dissolved plus reactive particulate phase] by Sea-Bird SBE 43 sensor and no calibration against sample data
FVLTZZ011VoltsRaw signal (voltage) of instrument output by in-situ chlorophyll fluorometer
IRRDUV011MicroEinsteins per square metre per secondDownwelling vector irradiance as photons of electromagnetic radiation (PAR wavelengths) in the water body by cosine-collector radiometer
OXYOCPVL1VoltsRaw signal (voltage) of instrument output by oxygen sensor
OXYSZZ011PercentSaturation of oxygen {O2 CAS 7782-44-7} in the water body [dissolved plus reactive particulate phase]
POPTDR011PercentTransmittance (red light wavelength) per 25cm of the water body by 25cm path length red light transmissometer
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
SVELCV011Metres per secondSound velocity in the water body by computation from temperature and salinity by unspecified algorithm
TEMPST011Degrees CelsiusTemperature of the water body by CTD or STD
TVLTDR011VoltsRaw signal (voltage) of instrument output by 25cm path length red light transmissometer

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

JR17006 CTD Data Quality Report

Screening and Quality Control

During BODC quality control, data were screened using in house visualisation software and any obvious outliers and spikes were looked at in closer detail and flagged if necessary.

POPTDR01

M flags were applied to several series where anomalous data were found, especially if spikes were identified but no similar features were identified in the Chlorophyll or Attenuation data.

ATTNMR01

M flags were applied to several series where anomalous data were found, especially if no similar features were identified in the transmittance data.

TVLTDR01

M flags were applied to cycles where improbable POPTDR01 and ATTNMR01 data were identified. These flags affect only those cycles where spikes were observed in POPTDR01.

OXYOCPVL

M flags were applied to all cycles where oxygen voltage was found to be zero. No flags were applied to the associated DOXYSU01 and OXYSZZ01 as the oxygen data were calibrated prior to being submitted.

AHSFZZ01

The altimeter only collects good data within 100 m of the seabed and all instances where values are constant or not decreasing with depth have been flagged M.

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 Dissolved Oxygen Sensor SBE 43 and SBE 43F

The SBE 43 is a dissolved oxygen sensor designed for marine applications. It incorporates a high-performance Clark polarographic membrane with a pump that continuously plumbs water through it, preventing algal growth and the development of anoxic conditions when the sensor is taking measurements.

Two configurations are available: SBE 43 produces a voltage output and can be incorporated with any Sea-Bird CTD that accepts input from a 0-5 volt auxiliary sensor, while the SBE 43F produces a frequency output and can be integrated with an SBE 52-MP (Moored Profiler CTD) or used for OEM applications. The specifications below are common to both.

Specifications

Housing Plastic or titanium
Membrane

0.5 mil- fast response, typical for profile applications

1 mil- slower response, typical for moored applications
Depth rating

600 m (plastic) or 7000 m (titanium)

10500 m titanium housing available on request
Measurement range 120% of surface saturation
Initial accuracy 2% of saturation
Typical stability 0.5% per 1000 h

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

JR17006 CTD Instrument Description

CTD Unit and Auxiliary Sensors

Sensor unit Model Serial number Full specification Calibration date
CTD underwater unit SBE 9plus 09P15759-0480 SBE 9plus  
CTD deck unit SBE 11plus 11P15759-0458    
Primary temperature sensor SBE 3P 2705 SBE 03P 25/05/2017
Secondary temperature sensor SBE 3P 5042 SBE 03P 25/05/2017
Primary conductivity sensor SBE 4C 2222 SBE 04C 24/05/2017
Secondary conductivity sensor SBE 4C 2255 SBE 04C 24/05/2017
Dissolved oxygen sensor SBE 43 2291 SBE 43 20/05/2017
Altimeter Tritech PA-200 244740 Tritech PA-200 24/05/2017
Irradiance sensor Biospherical QCP2350 PAR 70688 Biospherical QCP PAR sensor 20/06/2017
Fluorometer Chelsea MKIII Aquatracka

088-216 (casts 001 to 006)

088-249 (cast 007 to end)

 Chelsea MKII Aquatracka 19/05/2017
Transmissometer WetLabs C-Star CST-1399DR WetLabs C-Star 16/06/2017
LADCP RDI Workhorse 300 kHz

14897 (Master)

15060 (Slave)

 LADCP  

Sea-Bird Electronics SBE 911 and SBE 917 series CTD profilers

The SBE 911 and SBE 917 series of conductivity-temperature-depth (CTD) units are used to collect hydrographic profiles, including temperature, conductivity and pressure as standard. Each profiler consists of an underwater unit and deck unit or SEARAM. Auxiliary sensors, such as fluorometers, dissolved oxygen sensors and transmissometers, and carousel water samplers are commonly added to the underwater unit.

Underwater unit

The CTD underwater unit (SBE 9 or SBE 9 plus) comprises a protective cage (usually with a carousel water sampler), including a main pressure housing containing power supplies, acquisition electronics, telemetry circuitry, and a suite of modular sensors. The original SBE 9 incorporated Sea-Bird's standard modular SBE 3 temperature sensor and SBE 4 conductivity sensor, and a Paroscientific Digiquartz pressure sensor. The conductivity cell was connected to a pump-fed plastic tubing circuit that could include auxiliary sensors. Each SBE 9 unit was custom built to individual specification. The SBE 9 was replaced in 1997 by an off-the-shelf version, termed the SBE 9 plus, that incorporated the SBE 3 plus (or SBE 3P) temperature sensor, SBE 4C conductivity sensor and a Paroscientific Digiquartz pressure sensor. Sensors could be connected to a pump-fed plastic tubing circuit or stand-alone.

Temperature, conductivity and pressure sensors

The conductivity, temperature, and pressure sensors supplied with Sea-Bird CTD systems have outputs in the form of variable frequencies, which are measured using high-speed parallel counters. The resulting count totals are converted to numeric representations of the original frequencies, which bear a direct relationship to temperature, conductivity or pressure. Sampling frequencies for these sensors are typically set at 24 Hz.

The temperature sensing element is a glass-coated thermistor bead, pressure-protected inside a stainless steel tube, while the conductivity sensing element is a cylindrical, flow-through, borosilicate glass cell with three internal platinum electrodes. Thermistor resistance or conductivity cell resistance, respectively, is the controlling element in an optimized Wien Bridge oscillator circuit, which produces a frequency output that can be converted to a temperature or conductivity reading. These sensors are available with depth ratings of 6800 m (aluminium housing) or 10500 m (titanium housing). The Paroscientific Digiquartz pressure sensor comprises a quartz crystal resonator that responds to pressure-induced stress, and temperature is measured for thermal compensation of the calculated pressure.

Additional sensors

Optional sensors for dissolved oxygen, pH, light transmission, fluorescence and others do not require the very high levels of resolution needed in the primary CTD channels, nor do these sensors generally offer variable frequency outputs. Accordingly, signals from the auxiliary sensors are acquired using a conventional voltage-input multiplexed A/D converter (optional). Some Sea-Bird CTDs use a strain gauge pressure sensor (Senso-Metrics) in which case their pressure output data is in the same form as that from the auxiliary sensors as described above.

Deck unit or SEARAM

Each underwater unit is connected to a power supply and data logging system: the SBE 11 (or SBE 11 plus) deck unit allows real-time interfacing between the deck and the underwater unit via a conductive wire, while the submersible SBE 17 (or SBE 17 plus) SEARAM plugs directly into the underwater unit and data are downloaded on recovery of the CTD. The combination of SBE 9 and SBE 17 or SBE 11 are termed SBE 917 or SBE 911, respectively, while the combinations of SBE 9 plus and SBE 17 plus or SBE 11 plus are termed SBE 917 plus or SBE 911 plus.

Specifications

Specifications for the SBE 9 plus underwater unit are listed below:

Parameter Range Initial accuracy Resolution at 24 Hz Response time
Temperature -5 to 35°C 0.001°C 0.0002°C 0.065 sec
Conductivity 0 to 7 S m-1 0.0003 S m-1 0.00004 S m-1 0.065 sec (pumped)
Pressure 0 to full scale (1400, 2000, 4200, 6800 or 10500 m) 0.015% of full scale 0.001% of full scale 0.015 sec

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

Chelsea Technologies Group Aquatracka MKIII fluorometer

The Chelsea Technologies Group Aquatracka MKIII is a logarithmic response fluorometer. Filters are available to enable the instrument to measure chlorophyll, rhodamine, fluorescein and turbidity.

It uses a pulsed (5.5 Hz) xenon light source discharging along two signal paths to eliminate variations in the flashlamp intensity. The reference path measures the intensity of the light source whilst the signal path measures the intensity of the light emitted from the specimen under test. The reference signal and the emitted light signals are then applied to a ratiometric circuit. In this circuit, the ratio of returned signal to reference signal is computed and scaled logarithmically to achieve a wide dynamic range. The logarithmic conversion accuracy is maintained at better than one percent of the reading over the full output range of the instrument.

Two variants of the instrument are available, both manufactured in titanium, capable of operating in depths from shallow water down to 2000 m and 6000 m respectively. The optical characteristics of the instrument in its different detection modes are visible below:

Excitation Chlorophyll a Rhodamine Fluorescein Turbidity
Wavelength (nm) 430 500 485 440*
Bandwidth (nm) 105 70 22 80*
Emission Chlorophyll a Rhodamine Fluorescein Turbidity
Wavelength (nm) 685 590 530 440*
Bandwidth (nm) 30 45 30 80*

* The wavelengths for the turbidity filters are customer selectable but must be in the range 400 to 700 nm. The same wavelength is used in the excitation path and the emission path.

The instrument measures chlorophyll a, rhodamine and fluorescein with a concentration range of 0.01 µg l-1 to 100 µg l-1. The concentration range for turbidity is 0.01 to 100 FTU (other wavelengths are available on request).

The instrument accuracy is ± 0.02 µg l-1 (or ± 3% of the reading, whichever is greater) for chlorophyll a, rhodamine and fluorescein. The accuracy for turbidity, over a 0 - 10 FTU range, is ± 0.02 FTU (or ± 3% of the reading, whichever is greater).

Further details are available from the Aquatracka MKIII specification sheet.

Biospherical Instruments QCP-2350 [underwater] PAR sensor

A cosine-corrected PAR quantum irradiance profiling sensor. For use in underwater applications with 24 bit ADC systems. Measures light available for photosynthesis on a flat surface. Operation is by a single channel compressed analog output voltage that is proportional to the log of incident PAR (400-700 nm) irradiance. The sensor is designed for operation in waters to depths of up to 2,000 m (standard) or 6,800 m (optional).

For more information, please see this document: https://www.bodc.ac.uk/data/documents/nodb/pdf/Biospherical_QCP2300_QCP2350_Apr2014.pdf

Tritech Digital Precision Altimeter PA200

This altimeter is a sonar ranging device that gives the height above the sea bed when mounted vertically. When mounted in any other attitude the sensor provides a subsea distance. It can be configured to operate on its own or under control from an external unit and can be supplied with simultaneous analogue and digital outputs, allowing them to interface to PC devices, data loggers, telemetry systems and multiplexers.

These instruments can be supplied with different housings, stainless steel, plastic and aluminum, which will limit the depth rating. There are three models available: the PA200-20S, PA200-10L and the PA500-6S, whose transducer options differ slightly.

Specifications

Transducer options PA200-20S P200-10L PA500-6S
Frequency (kHz) 200 200 500
Beamwidth (°) 20 Conical 10 included conical beam 6 Conical
Operating range

1 to 100 m

0.7 to 50 m

 -

0.3 to 50 m

0.1 to 10 m

Common specifications are presented below

Digital resolution 1 mm
Analogue resolution 0.25% of range
Depth rating 700 , 2000, 4000 and 6800 m
Operating temperature -10 to 40°C

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

WETLabs C-Star transmissometer

This instrument is designed to measure beam transmittance by submersion or with an optional flow tube for pumped applications. It can be used in profiles, moorings or as part of an underway system.

Two models are available, a 25 cm pathlength, which can be built in aluminum or co-polymer, and a 10 cm pathlength with a plastic housing. Both have an analog output, but a digital model is also available.

This instrument has been updated to provide a high resolution RS232 data output, while maintaining the same design and characteristics.

Specifications

Pathlength 10 or 25 cm
Wavelength 370, 470, 530 or 660 nm
Bandwidth

~ 20 nm for wavelengths of 470, 530 and 660 nm

~ 10 to 12 nm for a wavelength of 370 nm
Temperature error 0.02 % full scale °C-1
Temperature range 0 to 30°C
Rated depth

600 m (plastic housing)

6000 m (aluminum housing)

Further details are available in the manufacturer's specification sheet or user guide.

JR17006 BODC CTD Data Processing

Data Processing

Processed and calibrated CTD data from Changing Arctic Ocean cruise JR17006 were submitted to BODC in csv format. The files were transferred to BODC internal format using standard BODC procedures. The variables provided in the files were mapped to BODC parameter codes as follows:

Originator's Variable Originator's Units BODC Parameter Code BODC Units Comment
CTDpres db PRESPR01 db -
CTDdepth m DEPHPR01 m This channel was dropped as can be derived from Pressure
CTDtemp1 °C TEMPST01 °C -
CTDtemp2 °C TEMPST02 °C The channel was transferred and then dropped following BODC processing as there was no difference in the quality of the data from the first or second sensor.
CTDsal1_cal PSU PSALST01 Dimensionless -
CTDsal2_cal PSU PSALST02 Dimensionless The channel was transferred and then dropped following BODC processing as there was no difference in the quality of the data from the first or second sensor.
CTDcond1_cal mS cm-1 CNDCST01 S m-1 Conversion of /10 applied
CTDcond2_cal mS cm-1 CNDCST02 S m-1 Conversion of /10 applied. The channel was transferred and then dropped following BODC processing as there was no difference in the quality of the data from the first or second sensor.
CTDfluor µg L-1 CPHLPR01 mg m-3 Equivalent units
CTDfluor_volts V FVLTZZ01 V  
CTDatt m-1 ATTNMR01 m-1 -
CTDatt_volts V TVLTDR01 V  
CTDxmiss % POPTDR01 %  
CTDpar µE cm-2 s-1 IRRDSV01 µE cm-2 s-1  
CTDaltim m AHSFZZ01 m  
CTDoxy_umol_cal µmol L-1 DOXYSC01 µmol L-1  
CTDoxy_volts V OXYOCPVL V  
CTDsound_vel1_cal m s-1 SVELCV01 m s-1  
CTDsound_vel2_cal m s-1 SVELCT01 m s-1 The channel was transferred and then dropped following BODC processing as there was no difference in the quality of the data from the first or second sensor.
    OXYSZZ01 % Derived during transfer using DOXYZZ01, TEMPST01 and PSALST01
    POTMCV01 °C Derived during transfer using TEMPST01, PSALST01 and PRESPR01
    POTMCV02 °C Derived during transfer using TEMPST02, PSALST02 and PRESPR01. Channel dropped as the data from the primary sensors was kept in the final files.
    SIGTPR01 kg m-3 Derived during transfer using POTMCV01, PSALST01 and PRESPR01
    SIGTPR02 kg m-3 Derived during transfer using POTMCV02, PSALST02 and PRESPR01. Channel dropped as the data from the primary sensors was kept in the final files.

Screening

Post transfer analysis and crosschecks were applied according to BODC procedures. This involved the screening of data using BODC's in house visualisation software where any suspect data were flagged but not removed.

JR17006 Originator CTD Data Processing

Sampling Strategy

A total of 62 CTD casts were performed during JR17006.

Data Processing

For each CTD cast the following raw data files were generated:

  • JR17006_XXX.bl (a record of bottle firing locations)
  • JR17006_XXX.hdr (header file)
  • JR17006_XXX.hex (raw data file)
  • JR17006_XXX.con (configuration file)

where XXX is the cast number of the CTD data series.

The CTD processing was started using Seabird Data Processing version 7.26.7 where the following modules were run:

  • Data conversion - converted raw data from engineering units to binary .cnv files using any calibrations in the instrument configuration file and created .ros files.
  • Wild edit - flagged any major spikes however this was not applied to conductivity and temperature as it resulted in bad data values of oxygen concentration after dynamic corrections.
  • Filter - smoothed the high frequency pressure and depth data using a low-pass filter (values of 0.15 - recommended by SeaBird).
  • AlignCTD - shifted conductivities and oxygen relative to pressure to compensate for sensor time lag.
  • CellTM - ran a recursive filter to remove conductivity cell thermal mass effects from measured conductivity.
  • Derive - derived computation variables from the processed pressure, temperature and conductivity.
  • Translate - converted the binary data to ASCII.
  • BottleSum - created .btl files using a five second window centered around the bottle firing time.
  • Strip - removed the first depth variable obtained at the Data Conversion stage.
  • Binavg - averaged all variables to 2Hz bins and 1 second bins for LADCP processing.
  • AsciiOut - reformatted the 1 second bin files for LADCP processing.

The originator then proceeded to process the data in Matlab version 2017b as follows:

  • reading and plotting of cnv files produced by the SeaBird modules
  • Creating bottle files, including standard deviation, minimum and maximum values over each 5 s window. SBE35 data were added when present
  • Manual removal of surface soak and post cast data
  • Splitting of upcast and downcast data
  • Manual removal of temperature spikes and anomalies
  • Automatic removal of salinity spikes
  • Application of salinity and oxygen calibration
  • Averaging to 1 db bins
  • Export to ascii (for both the 24 Hz and 1 db data)

Calibrations

Salinity

A total of 106 discrete salinity samples were analysed throughout the cruise, covering a wide range of salinity values. For each sample the bottle was rinsed 3 times with the Niskin seawater, filled, plastic insert fitted, bottle neck wiped and lid put on. Once a crate of 24 bottles was full, it was placed in the Autosal laboratory to acclimatise to temperature for at least one day prior to analysis. At the start and end of each crate a standard seawater (SSW) sample was analysed, in order to monitor the drift of the instrument. No clear drift pattern was visible, and the readings showed little difference from the theoretical value (less than 0.001 psu). For each crate, the average of the two SSW offsets was used as the offset to correct the Autosal readings.

There did not appear to be any temporal drift in the sensors, or a drift relative to pressure, so a constant offset was used to correct the data of both sensors. The median and standard deviation of the differences between the raw CTD and the Autosal readings were calculated, and all readings with a difference larger than 0.2 standard deviations of the median were excluded from the dataset. The median offset of each subset of selected points was then calculated and used as the correction offset.

  Samples rejected

Conductivity sensor

offset (mS cm-1)
Sensor 1 24 -0.0063
Sensor 2 22 -0.0035

Oxygen

Several samples were collected and analysed throughout the cruise, the final calibration equation was found to be

O2_cal = (O2_raw - 24.032) / 0.8942

Project Information

Changing Arctic Ocean: Implications for marine biology and biogeochemistry

Changing Arctic Ocean (CAO) is a £16 million, five year (2017-2022) research programme initially funded by the Natural Environment Research Council (NERC). The aim of the CAO programme is to understand how change in the physical environment (ice and ocean) will affect the large-scale ecosystem structure and biogeochemical functioning of the Arctic Ocean, the potential major impacts and provide projections for future ecosystem services. In July 2018, additional projects were added to the programme that were jointly funded by NERC and the German Federal Ministry of Education and Research.

Background

The Arctic Ocean is responding to global climate change in ways that are not yet fully understood and in some cases, not yet identified. The impacts of change in the Arctic are global in range and international in importance. To achieve the aim, the programme has two key research challenges:

  • To develop quantified understanding of the structure and functioning of Arctic ecosystems.
  • To understand the sensitivity of Arctic ecosystem structure, functioning and services to multiple stressors and the development of projections of the impacts of change.

The decision to fund the CAO project was both scientific and political and is the second largest research programme funded by NERC.

The programme involves 33 organisations, the majority of which are research institutions in the UK and Germany, and over 170 scientists. The programme consists of four large projects with an additional 12 research projects added in July 2018.

Further information can be found on the Changing Arctic Ocean website.

Participants

There are 33 organisations involved in the Changing Arctic Ocean project, these are:

  • Alfred Wegener Institut (AWI)
  • Bangor University
  • British Antarctic Survey (BAS)
  • Centre for Environment, Fisheries and Aquaculture Science (CEFAS)
  • Durham University
  • GEOMAR
  • Helmholtz-Zentrum Geesthacht Centre for Materials and Coastal Research
  • Lancaster University
  • Marine Biological Association (MBA)
  • Max Planck Institute for the Science of Human History
  • National Oceanography Centre (NOC)
  • Newcastle University
  • Northumbria University
  • Ocean Atmosphere Systems GmbH
  • Plymouth Marine Laboratory (PML)
  • Scottish Association for Marine Science (SAMS)
  • Scottish Universities Environmental Research Centre (SUERC)
  • Université Libre de Bruxelles
  • University College London (UCL)
  • University of Bristol
  • University of East Anglia (UEA)
  • University of Edinburgh
  • University of Glasgow
  • University of Huddersfield
  • University of Leeds
  • University of Liverpool
  • University of Manchester
  • University of Oldenburg
  • University of Oxford
  • University of Southampton
  • University of St Andrews
  • University of Stirling
  • University of Strathclyde

In addition to the core organisation, there are a number of international collaborators.

Research Details

The four large projects funded by NERC are:

  • Arctic Productivity in the seasonal Ice Zone (Arctic PRIZE)
  • Can we detect changes in Arctic ecosystems? (ARISE)
  • The Changing Arctic Ocean Seafloor (ChAOS) - How changing sea ice conditions impact biological communities, biogeochemical processes and ecosystems
  • Mechanistic understanding of the role of diatoms in the success of the Arctic Calanus complex and implications for a warmer Arctic (DIAPOD)

The additional 12 projects added in July 2018 funded jointly by NERC and the German Federal Ministry of Education and Research are:

  • Advective Pathways of nutrients and key Ecological substances in the Arctic (APEAR)
  • How will changing freshwater export and terrestrial permafrost thaw influence the Arctic Ocean? (CACOON)
  • Chronobiology of changing Arctic Sea Ecosystems (CHASE)
  • Potential benefits and risks of borealisation for fish stocks and ecosystems in a changing Arctic Ocean (Coldfish)
  • Diatom Autecological Responses with Changes To Ice Cover (Diatom-ARCTIC)
  • Ecosystem functions controlled by sea ice and light in a changing Arctic (Eco-Light)
  • Effects of ice stressors and pollutants on the Arctic marine cryosphere (EISPAC)
  • Linking Oceanography and Multi-specific, spatially-Variable Interactions of seabirds and their prey in the Arctic (LOMVIA)
  • Understanding the links between pelagic microbial ecosystems and organic matter cycling in the changing Arctic (Micro-ARC)
  • Microbes to Megafauna Modelling of Arctic Seas (MiMeMo)
  • Primary productivity driven by escalating Arctic nutrient fluxes? (PEANUTS)
  • Pathways and emissions of climate-relevant trace gases in a changing Arctic Ocean (PETRA)

Fieldwork and Data Collection

The programme consists of seven core cruises that survey areas in the Barents Sea and the Fram Strait on board the NERC research vessel RRS James Clark Ross. Measurements will include temperature, salinity, dissolved oxygen, dissolved inorganic carbon, total alkalinity, inorganic nutrients, oxygen and carbon isotopes and underway meteorological and surface ocean observations. In addition to ship based cruise datasets gliders, moorings and animal tags are part of the fieldwork. Further data are collected from model runs.

Data Activity or Cruise Information

Cruise

Cruise Name JR17006
Departure Date 2018-06-11
Arrival Date 2018-07-06
Principal Scientist(s)Finlo R Cottier (Scottish Association for Marine Science)
Ship RRS James Clark Ross

Complete Cruise Metadata Report is available here

Fixed Station Information


No Fixed Station Information held for the Series

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
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