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  • PANGAEA  (5)
Collection
Keywords
Years
  • 1
    Publication Date: 2023-03-07
    Description: During the cruise the turbulence probe MSS050 was used for microstructure measurements. The profiler is produced by Sea and Sun Technology GmbH in co-operation with ISW Wassermesstechnik. The probe was equipped with 2 velocity microstructure shear sensors, a microstructure temperature sensor, standard CTD sensors for precision measurements, a vibration control sensor, a two component tilt sensor, a fluorescence sensor and surface detection sensor (SD) to indicate the water surface hit at rising measurements. The sampling rate for all sensors is 1024 samples per second, the resolution 16 bit. During the MSS measurements, the ship was moving with speed approx. 0.5-1.0 knots with respect to the water against the wind. In order to take into account the intermittent nature of marine turbulence, repeated MSS measurements were carried out in bursts of typically 10 profiles per station. The measurement interval was approximately 7 (10) min for a profile to 140 (200) dbar. During JC87 cruise 8 series of turbulence measurements were conducted. Fluorescence data was obtained on the 5 of them.
    Keywords: Basin Scale Analysis, Synthesis and Integration; Date/Time of event; Date/Time of event 2; EURO-BASIN; Event label; James Cook; JC087; JC087-003; JC087-008; JC087-030; JC087-052; JC087-061; JC087-073; JC087-095; JC087-131; JC087-142; Latitude of event; Latitude of event 2; Longitude of event; Longitude of event 2; Number; Porcupine Abyssal Plain; Pressure, atmospheric; Turbulence probe; Turbulence probe MSS050; TURPRO; Wave height; Wave period; Wind direction; Wind speed
    Type: Dataset
    Format: text/tab-separated-values, 749 data points
    Location Call Number Expected Availability
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  • 2
    Publication Date: 2024-02-02
    Keywords: Basin Scale Analysis, Synthesis and Integration; Bottle number; CTD/Rosette; CTD-RO; Date/Time of event; Deep Convection Cruise; DEPTH, water; EURO-BASIN; Event label; Latitude of event; Longitude of event; M87/1_413-1; M87/1_421-1; M87/1_434-1; M87/1_444-1; M87/1_447-1; M87/1_460-1; M87/1_466-1; M87/1_482-1; M87/1_505-1; M87/1_508-1; M87/1_516-1; M87/1_532-1; M87/1_551-1; M87/1_553-1; M87/1_572-1; M87/1_581-1; M87/1_582-1; M87/1_583-1; M87/1_600-1; M87/1_610-1; M87/1_614-1; M87/1_618-1; M87/1_638-1; M87/1_641-1; M87/1_667-1; M87/1_671-1; M87/1_672-1; M87/1_689-1; M87/1_702-1; M87/1a; M87/1b; Meteor (1986); Nitrate and Nitrite; Phosphate; Silicate; Station 1; Station 2; Station 3
    Type: Dataset
    Format: text/tab-separated-values, 2172 data points
    Location Call Number Expected Availability
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  • 3
    facet.materialart.
    Unknown
    PANGAEA
    In:  Supplement to: Daniels, Chris J; Poulton, Alex J; Esposito, Mario; Paulsen, Maria Lund; Bellerby, Richard G J; St John, M; Martin, Adrian Peter (2015): Phytoplankton dynamics in contrasting early stage North Atlantic spring blooms: composition, succession, and potential drivers. Biogeosciences, 12(8), 2395-2409, https://doi.org/10.5194/bg-12-2395-2015
    Publication Date: 2024-02-02
    Description: The Deep Convection cruise repeatedly sampled two locations in the North Atlantic, sited in the Iceland and Norwegian Basins, onboard the RV Meteor (19 March - 2 May 2012). Samples were collected from multiple casts of a conductivity-temperature-depth (CTD) - Niskin rosette at each station. Water samples for primary production rates, community structure, chlorophyll a [Chl a], calcite [PIC], particulate organic carbon [POC] and biogenic silicic acid [BSi] were collected from predawn casts from six light depths (55%, 20%, 14%, 7%, 5% and 1% of incident PAR). Additional samples for community structure and ancillary parameters were collected from a second cast. Carbon fixation rates were determined using the 13C stable isotope method. Water samples for diatom and micro zooplankton counts, collected from the predawn casts, were preserved with acidic Lugol's solution (2% final solution) and counted using an inverted light microscope. Water samples for coccolithophore counts were collected onto cellulose nitrate filters and counted using polarising light microscopy. Water samples for Chl a analysis were filtered onto MF300 and polycarbonate filters and extracted in 90% acetone. PIC and BSi samples were filtered onto polycarbonate filters and analysed using an inductively coupled plasma emission optical spectrometer and a SEAL QuAAtro autoanalyser respectively.
    Keywords: Basin Scale Analysis, Synthesis and Integration; Biogenic silica; Bottle number; Carbon, inorganic, particulate; Carbon, organic, particulate; Chaetoceros spp.; Chlorophyll a as carbon; Ciliates; Coccolithus leptoporus; Coccolithus pelagicus; Coronosphaera mediterranea; Counting; Cryptophytes; CTD/Rosette; CTD-RO; Cylindrotheca spp.; Dactyliosolen spp.; Date/Time of event; Deep Convection Cruise; DEPTH, water; Diatoms, centrales indeterminata; Diatoms, pennales indeterminata; Dinoflagellates, armoured; Emiliania huxleyi; EURO-BASIN; Event label; Guinardia striata; Gymnodinium spp.; Gyrodinium spp.; Latitude of event; Leptocylindrus spp.; Longitude of event; M87/1_413-1; M87/1_421-1; M87/1_447-1; M87/1_460-1; M87/1_516-1; M87/1_532-1; M87/1_553-1; M87/1_572-1; M87/1_614-1; M87/1_618-1; M87/1_641-1; M87/1_667-1; M87/1_672-1; M87/1_689-1; M87/1a; M87/1b; Meteor (1986); Navicula spp.; Primary production, carbon assimilation (24 hr.); Pseudo-nitzschia spp.; Rhizosolenia spp.; Silicoflagellates; Station 1; Station 2; Syracosphaera pulchra; Thalassionema spp.; Thalassiosira spp.
    Type: Dataset
    Format: text/tab-separated-values, 832 data points
    Location Call Number Expected Availability
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  • 4
    facet.materialart.
    Unknown
    PANGAEA
    In:  Supplement to: Torres-Valdés, Sinhué; Painter, Stuart; Martin, Adrian Peter; Sanders, Richard J; Felden, Janine (2014): Data compilation of fluxes of sedimenting material from sediment traps in the Atlantic Ocean. Earth System Science Data, 6, 123-145, https://doi.org/10.5194/essd-6-123-2014
    Publication Date: 2024-03-21
    Description: We provide a compilation of downward fluxes (total mass, POC, PON, BSiO2, CaCO3, PIC and lithogenic/terrigenous fluxes) from over 6000 sediment trap measurements distributed in the Atlantic Ocean, from 30 degree North to 49 degree South, and covering the period 1982-2011. Data from the Mediterranean Sea are also included. Data were compiled from different sources: data repositories (BCO-DMO, PANGAEA), time series sites (BATS, CARIACO), published scientific papers and/or personal communications from PI's. All sources are specifed in the data set. Data from the World Ocean Atlas 2009 were extracted to provide each flux observation with contextual environmental data, such as temperature, salinity, oxygen (concentration, AOU and percentage saturation), nitrate, phosphate and silicate.
    Keywords: 11880-011; 12812-002; 12930-035; 13077-062; 13200-096; 13368-055; 13627-025; 19°N20°W; 19°N20°W_trap; 24°N23°W; 24°N23°W_trap; 28°N22°W; 28°N22°W_trap; 485; 55002-002; after Torres Valdés et al., 2013; ANT-III/2; ANT-IV/2; ANT-IV/3; ANT-V/4; ANT-VII/5; ANT-XII/2; ANT-XII/4; Apparent oxygen utilisation, water, interpolated; Arctic Ocean; ARCT-L3; ARK-XI/1; ARK-XVI/2; ARK-XVII/1; ARK-XVIII/1; ARK-XX/1; AT_II-119/4_22-2; AT_II-119/4_9-2; AT_II-119/4_Trap_A; AT_II-119/4_Trap_B; AT_II-119/5_Trap_C; Atlantic; Atlantic_Province; Atlantic Ocean; Atlantis_II-119/4; Atlantis_II-119/5; Atlantis II (1963); BAF89/3; BAF89/3_FTRAP1; BAF89/3_FTRAP2; Baffin; Basin Scale Analysis, Synthesis and Integration; BATS; BATS_SedTrap_10003; BATS_SedTrap_10004; BATS_SedTrap_10005; BATS_SedTrap_10006; BATS_SedTrap_10007; BATS_SedTrap_10008; BATS_SedTrap_10009; BATS_SedTrap_10010; BATS_SedTrap_10011; BATS_SedTrap_10013; BATS_SedTrap_10014; BATS_SedTrap_10016; BATS_SedTrap_10017; BATS_SedTrap_10018; BATS_SedTrap_10019; BATS_SedTrap_10020; BATS_SedTrap_10021; BATS_SedTrap_10022; BATS_SedTrap_10023; BATS_SedTrap_10025; BATS_SedTrap_10026; BATS_SedTrap_10027; BATS_SedTrap_10028; BATS_SedTrap_10029; BATS_SedTrap_10030; BATS_SedTrap_10031; BATS_SedTrap_10032; BATS_SedTrap_10033; BATS_SedTrap_10034; BATS_SedTrap_10035; BATS_SedTrap_10036; BATS_SedTrap_10037; BATS_SedTrap_10038; BATS_SedTrap_10039; BATS_SedTrap_10040; BATS_SedTrap_10041; BATS_SedTrap_10042; BATS_SedTrap_10043; BATS_SedTrap_10044; BATS_SedTrap_10045; BATS_SedTrap_10046; BATS_SedTrap_10047; BATS_SedTrap_10048; BATS_SedTrap_10049; BATS_SedTrap_10050; BATS_SedTrap_10051; BATS_SedTrap_10052; BATS_SedTrap_10053; BATS_SedTrap_10054; BATS_SedTrap_10055; BATS_SedTrap_10056; BATS_SedTrap_10057; BATS_SedTrap_10058; BATS_SedTrap_10059; BATS_SedTrap_10060; BATS_SedTrap_10061; BATS_SedTrap_10062; BATS_SedTrap_10063; BATS_SedTrap_10064; BATS_SedTrap_10065; BATS_SedTrap_10066; BATS_SedTrap_10067; BATS_SedTrap_10068; BATS_SedTrap_10069; BATS_SedTrap_10070; BATS_SedTrap_10071; BATS_SedTrap_10072; BATS_SedTrap_10073; BATS_SedTrap_10074; BATS_SedTrap_10075; BATS_SedTrap_10076; BATS_SedTrap_10077; BATS_SedTrap_10078; BATS_SedTrap_10079; BATS_SedTrap_10080; BATS_SedTrap_10081; BATS_SedTrap_10082; BATS_SedTrap_10083; BATS_SedTrap_10084; BATS_SedTrap_10085; BATS_SedTrap_10086; BATS_SedTrap_10087; BATS_SedTrap_10088; BATS_SedTrap_10089; BATS_SedTrap_10090; BATS_SedTrap_10091; BATS_SedTrap_10092; BATS_SedTrap_10093; BATS_SedTrap_10094; BATS_SedTrap_10095; BATS_SedTrap_10096; BATS_SedTrap_10097; BATS_SedTrap_10098; BATS_SedTrap_10099; BATS_SedTrap_10100; BATS_SedTrap_10101; BATS_SedTrap_10102; BATS_SedTrap_10103; BATS_SedTrap_10104; BATS_SedTrap_10105; BATS_SedTrap_10106; BATS_SedTrap_10107; BATS_SedTrap_10108; BATS_SedTrap_10109; BATS_SedTrap_10110; BATS_SedTrap_10111; BATS_SedTrap_10112; BATS_SedTrap_10113; BATS_SedTrap_10114; BATS_SedTrap_10115; BATS_SedTrap_10116; BATS_SedTrap_10117; BATS_SedTrap_10118; BATS_SedTrap_10119; BATS_SedTrap_10120; BATS_SedTrap_10122; BATS_SedTrap_10123; BATS_SedTrap_10124; BATS_SedTrap_10125; BATS_SedTrap_10126; BATS_SedTrap_10127; BATS_SedTrap_10128; BATS_SedTrap_10129; BATS_SedTrap_10130; BATS_SedTrap_10131; BATS_SedTrap_10132; BATS_SedTrap_10133; BATS_SedTrap_10134; BATS_SedTrap_10136; BATS_SedTrap_10137; BATS_SedTrap_10138; BATS_SedTrap_10139; BATS_SedTrap_10140; BATS_SedTrap_10141; BATS_SedTrap_10142; BATS_SedTrap_10143; BATS_SedTrap_10144; BATS_SedTrap_10145; BATS_SedTrap_10146; BATS_SedTrap_10147; BATS_SedTrap_10148; BATS_SedTrap_10149; BATS_SedTrap_10150; BATS_SedTrap_10151; BATS_SedTrap_10152; BATS_SedTrap_10153; BATS_SedTrap_10154; BATS_SedTrap_10155; BATS_SedTrap_10156; BATS_SedTrap_10158; BATS_SedTrap_10159; BATS_SedTrap_10161; BATS_SedTrap_10162; BATS_SedTrap_10163; BATS_SedTrap_10164; BATS_SedTrap_10165; BATS_SedTrap_10166; BATS_SedTrap_10167; BATS_SedTrap_10168; BATS_SedTrap_10170; BATS_SedTrap_10171; BATS_SedTrap_10172; BATS_SedTrap_10173; BATS_SedTrap_10174; BATS_SedTrap_10175; BATS_SedTrap_10176; BATS_SedTrap_10177; BATS_SedTrap_10178; BATS_SedTrap_10179; BATS_SedTrap_10180; BATS_SedTrap_10181; BATS_SedTrap_10182; BATS_SedTrap_10183; BATS_SedTrap_10184; BATS_SedTrap_10185; BATS_SedTrap_10187; BATS_SedTrap_10188; BATS_SedTrap_10189; BATS_SedTrap_10190; BATS_SedTrap_10191; BATS_SedTrap_10192; BATS_SedTrap_10193; BATS_SedTrap_10194; BATS_SedTrap_10195; BATS_SedTrap_10196; BATS_SedTrap_10197; BATS_SedTrap_10198; BATS_SedTrap_10199; BATS_SedTrap_10200; BATS_SedTrap_10201; BATS_SedTrap_10202; BATS_SedTrap_10203; BATS_SedTrap_10204; BATS_SedTrap_10205; BATS_SedTrap_10206; BATS_SedTrap_10207; BATS_SedTrap_10208; BATS_SedTrap_10209; BATS_SedTrap_10210; BATS_SedTrap_10211; BATS_SedTrap_10212; BATS_SedTrap_10213; BATS_SedTrap_10214; BATS_SedTrap_10215; BATS_SedTrap_10216; BATS_SedTrap_10217; BATS_SedTrap_10218; BATS_SedTrap_10219; BATS_SedTrap_10220; BATS_SedTrap_10221; BATS_SedTrap_10222; BATS_SedTrap_10223; BATS_SedTrap_10224; BATS_SedTrap_10225; BATS_SedTrap_10226; BATS_SedTrap_10227; BATS_SedTrap_10228; BATS_SedTrap_10229; BATS_SedTrap_10230; BATS_SedTrap_10231; BATS_SedTrap_10232; BATS_SedTrap_10233; BATS_SedTrap_10234; BATS_SedTrap_10235; BATS_SedTrap_10236; BATS_SedTrap_10237; BATS_SedTrap_10238; BATS_SedTrap_10239; BATS_SedTrap_10240; BATS_SedTrap_10241; BATS_SedTrap_10242; BATS_SedTrap_10243; BATS_SedTrap_10244; BATS_SedTrap_10245; BATS_SedTrap_10246; BATS_SedTrap_10247; BATS_SedTrap_10248; BATS_SedTrap_10249; BATS_SedTrap_10250; BATS_SedTrap_10251; BATS_SedTrap_10252; BATS_SedTrap_10253; BATS_SedTrap_10254; BATS_SedTrap_10256; BATS_SedTrap_10257; BATS_SedTrap_10258; BATS_SedTrap_10259; BATS_SedTrap_10260; BATS_SedTrap_10261; BATS_SedTrap_10262; BATS_SedTrap_10263; BATS_SedTrap_10264; BATS_SedTrap_10265; BATS_SedTrap_10266; BATS_SedTrap_10267; BATS_SedTrap_10268; BATS_SedTrap_10269; BATS_SedTrap_10270; BATS_SedTrap_20267; Bermuda Atlantic Time-Series Study; Biogenic silica, particulate, flux per day; BO1; BO1_trap; BO1/2; BO1/2_trap; BO2_trap; BO3; BO3_trap; BO5; BO5_trap; Bouvet Island; Calcium carbonate, flux; Cape Blanc; Cape Verde Abyssal Plateau; Cape Verde Terrace; Carbon, inorganic, particulate, flux per day; Carbon, organic, particulate, flux; Carbon, organic, particulate, flux, standard deviation; CARIACO_Trap_1995; CARIACO_Trap_1996; CARIACO_Trap_1997_1; CARIACO_Trap_1997_2; CARIACO_Trap_1998_1; CARIACO_Trap_1998_2; CARIACO_Trap_1999_1; CARIACO_Trap_1999_2; CARIACO_Trap_2000_1; CARIACO_Trap_2000_2; CARIACO_Trap_2001; CARIACO_Trap_2002_1; CARIACO_Trap_2002_2; CARIACO_Trap_2003_1; CARIACO_Trap_2003_2; CARIACO_Trap_2004_1; CARIACO_Trap_2004_2; CARIACO_Trap_2005_1; CARIACO_Trap_2005_2; CARIACO_Trap_2006_1; CARIACO_Trap_2006_2; CARIACO_Trap_2007_1; CARIACO_Trap_2007_2; CARIACO_Trap_2008_1; CARIACO_Trap_2008_2; CARIACO_Trap_2009_1; CARIACO_Trap_2009_2; CARIACO_Trap_2010_1; Cariaco Basin; CB1_trap; CB17; CB17_trap; CB2_trap; CB3_trap; CB4_trap; CB5_trap; CB7; CB7_trap; CB9_trap; CD91B; CD93A; CH121C; CH125A; CH126A; Challenger; Charles Darwin; CI1; CI1_trap; CI2; CI2_trap; CI3; CI3_trap; CI4; CI4_trap; Comment; CV1-2_trap; CV2; CV2_trap; D217; D222/2; D226; D229; D231; D237; DATE/TIME; Date/time end; DEPTH, water; Discovery (1962); Dissolved oxygen, in water, interpolated; Dissolved oxygen saturation, water, interpolated; DRIFT; DRIFT1; DRIFT2; Drifter; Drifter, daily; Duration, number of days; DYF1; DYF10; DYF11; DYF12; DYF13; DYF14; DYF16; DYF17; DYF18; DYF19; DYF20; DYF21; DYF23; DYF24; DYF25; DYF26; DYF27; DYF2-Calvi; DYF3; DYF3-Calvi; DYF4; DYF5; DYF6; DYF6-Calvi; DYF7; DYF7-Calvi; DYF8; DYF9; DYFAMED; DYNAPROC; DYNAPROC_TRAP; EA1_trap; EA10; EA10_trap; EA2_trap; EA3_trap; EA4_trap; EA5_trap; EA6; EA6_trap; EA7; EA7_trap; EA8; EA8_trap; EA9; EA9_trap; East Equatorial Atlantic; Eastern equatorial Atlantic; EUMELI-MESO-TRAPS; EUMELI-OLIGO-TRAPS; EURO-BASIN; Event label; FEVI1; FEVI2; FEVI3; FEVI4; FEVI7; GB2; GB2_trap; GBN3_trap; GBN6_trap; GBS4_trap; GBS5; GBS5_trap; GBZ4_trap; Gear;
    Type: Dataset
    Format: text/tab-separated-values, 125873 data points
    Location Call Number Expected Availability
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  • 5
    Publication Date: 2024-05-14
    Description: Physical, chemical and biogeochemical measurements derived from CTD-rosette deployments during three visits to site P3 (November to December, 2017) in the South Atlantic. Measurements were made during COMICS cruise DY086 on the RRS Discovery using a trace metal free Titanium Rosette (events 4, 7, 15, 19, 24, 26, 29) and a Stainless Steel Rosette (all other events). Physical parameters include temperature, salinity, density, photosynthetically active radiation and turbulence; chemical parameters include dissolved oxygen, dissolved oxygen saturation, nitrate, phosphate and silicate; biogeochemical parameters include turbidity, beam transmittance, beam attenuation, fluorescence, particulate organic carbon (POC), dissolved organic carbon (DOC), chlorophyll-a, net primary productivity (NPP), ambient leucine assimilation and bacterial cell count. To determine turbulence, a downward facing lowered acoustic doppler current profiler (LADCP, Teledyne Workhorse Monitor 300 kHz ADCP) was attached to the CTD frame. Shear and strain, which are obtained from velocity and density measurements, were used to estimate the dissipation rate of turbulent kinetic energy and the diapycnal eddy diffusivity from a fine-scale parameterisation. Estimates are calculated by parameterising internal wave-wave interactions and assuming that wave breaking modulates turbulent mixing. A detailed description of the method for calculating diffusivity from LADCP and CTD can be found in Kunze et al. (2006). Two datasets with different vertical resolutions were produced: one in which the shear is integrated from 150 to 300 m and the strain over 20-150 m, and one in which the shear is integrated from 70 to 200 m and the strain over 30-200 m. Nutrients (nitrate, phosphate, silicate) were determined via colourimetric analysis (see cruise report, Giering and Sanders, 2019), POC was determined as described in Giering et al. (2023), DOC and DOC flux were determined as described in Lovecchio et al. (2023), NPP was determined as described in Poulton et al. (2019), and ambient leucine assimilation and bacterial cell count were determined as described in Rayne et al. (2024). Bacterial abundance and leucine assimilation were made from bottle samples of six CTD casts of the stainless-steel rosette. Water was collected at six depths (6 m, deep-chlorophyll maximum, mixed layer depth + 10, 100, 250 and 500 m). Acid-cleaned HDPE carboys and tubing were used for sampling. Samples were then stored in the dark and at in-situ temperature prior to on-board laboratory sample preparation or analysis. Flow cytometry was used to measure bacterial abundance. Room temperature paraformaldehyde was used to fix 1.6 ml samples for 30 minutes. Then, using liquid nitrogen, the samples were flash frozen and stored at -80°C. Samples were then defrosted before being stained using SYBR Green I and run through the flow cytometer (BD FACSort™). The method of Hill et al. (2013) was applied to determine prokaryotic leucine assimilation using L-[4,5-³H] leucine which has a specific activity of 89.3 Ci/mmol­. In the mixed and upper layers of the water column, the protocol in Zubkov et al. (2007) was followed. Below the mixed layer, adaptions to the method included reducing the concentration of ³H-Leucine to 0.005, 0.01, 0.025, 0.04 and 0.05 nM; increasing experimental volumes to 30 ml; enhancing incubation times to 30, 60, 90 and 120 min. These adaptions were made to improve accuracy where lower rates of leucine assimilation were expected. Data were provided by the British Oceanographic Data Centre and funded by the National Environment Research Council.
    Keywords: 74EQ20171115; Angular scattering coefficient, 700 nm; Attenuation, optical beam transmission; Bacteria; Barometer, Paroscientific, Digiquartz TC; biological carbon pump; Calculated; Calculated according to UNESCO (1983); Calculation according to Kunze et al. (2006); Carbon, organic, dissolved; Carbon, organic, dissolved, flux; Carbon, organic, particulate; Chlorophyll a; Colorimetric analysis; COMICS; Conductivity sensor, SEA-BIRD SBE 4C; Controls over Ocean Mesopelagic Interior Carbon Storage; CTD/Rosette; CTD-RO; DATE/TIME; Density, sigma-theta (0); DEPTH, water; Discovery (2013); Dissipation rate; Dissolved Oxygen Sensor, Sea-Bird, SBE 43 and SBE 43F; DY086; DY086_CTD002; DY086_CTD003; DY086_CTD004; DY086_CTD005; DY086_CTD006; DY086_CTD007; DY086_CTD008; DY086_CTD009; DY086_CTD010; DY086_CTD015; DY086_CTD016; DY086_CTD017; DY086_CTD018; DY086_CTD019; DY086_CTD020; DY086_CTD021; DY086_CTD022; DY086_CTD023; DY086_CTD024; DY086_CTD026; DY086_CTD027; DY086_CTD028; DY086_CTD029; DY086_CTD030; DY086_CTD031; DY086_CTD032; DY086_CTD033; Eddy diffusivity; Event label; Flow cytometer, Becton Dickinson, FACSort; Fluorometer, Chelsea Instruments, Aquatracka MKIII; fluxes; High Temperature Catalytic Oxidation, Shimadzu TOC-VCPN; LATITUDE; Leucine uptake rate; Liquid scintillation counter, Packard, TRI-CARB 3100TR; LONGITUDE; marine biogeochemistry; Net primary production of carbon; Nitrate; Organic Elemental Analyzer, Thermo Fisher Scientific, Flash 2000; Oxygen; Oxygen saturation; PAR sensor, Biospherical, LI-COR, SN 70510; PAR sensor, Biospherical, LI-COR, SN 70520; Phosphate; Radiation, photosynthetically active; Radioassays, liquid scintillation counting; Salinity; Scattering meter, WET Labs, ECO-BB OBS; Silicate; Site; SUMMER; Sustainable Management of Mesopelagic Resources; Temperature, water; Temperature sensor, SEA-BIRD SBE 3Plus; Transmissometer, WET Labs, C-Star
    Type: Dataset
    Format: text/tab-separated-values, 171794 data points
    Location Call Number Expected Availability
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