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de Jonge, Danielle; Gaurisas, Daniela Y; Smith, Alycia J; Holmes, Eloise; Orejas, Covadonga; Mosquera Giménez, Ángela; Roberts, J Murray; Bernadino, Angelo; Sweetman, Andrew K (2024): Benthic Chamber Lander stable isotope tracer experiments in the Cabo Verde Abyssal Basin (tropical East Atlantic) [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.963084

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Published: 2024-07-02DOI registered: 2024-07-31

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Abstract:
A total of five deployments of a Benthic Chamber Lander were conducted at the Cabo Verde Abyssal Plain (tropical East Atlantic) at about 4200 m water depth. The deployments took place from the research vessel Sarmiento de Gamboa during the iMirabilis2 campaign in August 2021. Each deployment carried three functional chambers, one conducting a stable isotope tracer experiment, and two collecting background data. The stable isotope tracer used was axenically cultured and lyophilised diatoms (Phaeodactylum tricornutum) labelled with 13C and 15N. The experiment had a duration of 48 hours. The chamber carried an oxygen optode (Aanderaa 4330F) for continuous oxygen concentration measurements used to determine sediment community oxygen consumption (SCOC). During the experiment seven water samples were collected at hours T0.33, T2, T10, T19, T28, T37, and T46. The water samples were processed for oxygen concentration (Micro-Winkler Titration) as a second method to determine SCOC, Dissolved Inorganic Carbon (DIC and DI13C) concentration in order to calculate the substrate-derived respiration rate, and nutrients (NH4, NO2, NO3, PO4, Si) concentrations to determine nutrient fluxes. The sediments were sampled after lander recovery. Sediments were analysed for Total Organic Carbon (TOC and TO13C) in order to establish if injection was successful and get a carbon content sediment profile. Sediments were analysed for Phospholipid-derived Fatty Acid (PLFA) biomarkers including their 13C stable isotope signal, in order to calculate bacterial biomass and tracer incorporation during the incubation. Sediment samples for macrofauna, large Foraminifera, and meiobenthos were preserved in 4% buffered formaldehyde, then transferred to ethanol, until analysis. Meiobenthos was extracted using LUDOX density separation and a 32 µm mesh, and identified to 'Nematoda' and 'Other meiobenthos' for the 0-2 and the 2-5 cm sediment horizons, in order to calculate meiobenthic densities. Sediments for macrofauna and large Foraminifera were washed over a 300 µm mesh and picked for identification and determining densities. After identification, samples were dried at 45 °C until stable mass. For calcareous organisms, the sample was acidified, and dried at 45 °C again. Dried samples were analysed for dry mass, carbon and nitrogen content and stable isotope signals (13C, 15N). C and N incorporation rates were calculated from stable isotope signals.
Keyword(s):
Abyssal plain; Bacteria; benthic lander; Cabo Verde; carbon isotope ratios; dissolved inorganic carbon (DIC); Foraminifera; incubation experiment; Macrobenthos; Meiobenthos; nitrogen isotope ratios; nutrient fluxes; oxygen consumption; PLFA; respiration flux; stable isotope labelling; total organic carbon (TOC)
Related to:
Orejas, Covadonga; Huvenne, Veerle A I; Sweetman, Andrew K; Vinha, Beatrix; Abella, Joan Carles; Andrade, Pablo; Alfonso, Andreia; Antelo, Juan; Austin-Berry, Richard; Baltasar, Lino; Nadito, Barbosa; Barnhill, Kelsey Archer; Barreiro, A; Bettencourt, Renato; de Jonge, Danielle; González-Solís, Jacob; Gori, Andrea; Gunn, Vikki; Menéndez, M; Raddatz, Jacek; Ramos, B; Rodriguez, Pablo; Sanchez, Mario Villatoro; Simon-Lledó, Erik; Smith, Andrew; Vélez-Belchí, Pedro (2022): Expedition report iMirabilis2 survey. Zenodo, https://doi.org/10.5281/zenodo.6352141
References:
Bittig, Henry C; Körtzinger, Arne; Neill, Craig; van Ooijen, Eikbert; Plant, Joshua N; Hahn, Johannes; Johnson, Kenneth S; Yang, Bo; Emerson, Steven R (2018): Oxygen Optode Sensors: Principle, Characterization, Calibration, and Application in the Ocean. Frontiers in Marine Science, 4, 429, https://doi.org/10.3389/fmars.2017.00429
Kamenskaya, Olga E; Melnik, V F; Gooday, Andrew J (2013): Giant protists (xenophyophores and komokiaceans) from the Clarion-Clipperton ferromanganese nodule field (eastern Pacific). Biology Bulletin Reviews, 3(5), 388-398, https://doi.org/10.1134/S2079086413050046
Rohal, Melissa; Thistle, David; Easton, Erin E (2018): Extraction of metazoan meiofauna from muddy deep-sea samples: Operator and taxon effects on efficiency. Journal of Experimental Marine Biology and Ecology, 502, 105-110, https://doi.org/10.1016/j.jembe.2017.01.006
Shahbaz, Muhammad; Kätterer, Thomas; Thornton, Barry; Börjesson, Gunnar (2020): Dynamics of fungal and bacterial groups and their carbon sources during the growing season of maize in a long-term experiment. Biology and Fertility of Soils, 56(6), 759-770, https://doi.org/10.1007/s00374-020-01454-z
Thornton, Barry; Zhang, Z; Mayes, Robert W; Högberg, Mona N; Midwood, Andrew J (2011): Can gas chromatography combustion isotope ratio mass spectrometry be used to quantify organic compound abundance? Rapid Communications in Mass Spectrometry, 25(17), 2433-2438, https://doi.org/10.1002/rcm.5148
Project(s):
Integrated Assessment of Atlantic Marine Ecosystems in Space and Time (iAtlantic)
Funding:
Horizon 2020 (H2020), grant/award no. 818123: Integrated Assessment of Atlantic Marine Ecosystems in Space and Time
Coverage:
Median Latitude: 14.719020 * Median Longitude: -25.168920 * South-bound Latitude: 14.710000 * West-bound Longitude: -25.202100 * North-bound Latitude: 14.732300 * East-bound Longitude: -25.126800
Date/Time Start: 2021-08-06T00:00:00 * Date/Time End: 2021-08-22T02:00:00
Minimum Elevation: -4215.0 m * Maximum Elevation: -4168.0 m
Event(s):
iMirabilis2_Leg1_9_AKS295 (iMirabilis2 station 9) * Latitude: 14.719000 * Longitude: -25.202100 * Date/Time: 2021-08-06T00:00:00 * Elevation: -4168.0 m * Location: NW-Africa, Cabo Verde Abyssal Plain * Campaign: iMirabilis2_Leg1 * Basis: Sarmiento de Gamboa * Method/Device: Benthic chamber lander (BCL) * Comment: One experimental chamber, two background chambers.
iMirabilis2_Leg1_28_AKS300 (iMirabilis2 station 28) * Latitude: 14.711900 * Longitude: -25.191900 * Date/Time: 2021-08-11T00:00:00 * Elevation: -4178.0 m * Location: NW-Africa, Cabo Verde Abyssal Plain * Campaign: iMirabilis2_Leg1 * Basis: Sarmiento de Gamboa * Method/Device: Benthic chamber lander (BCL) * Comment: One experimental chamber, two background chambers.
iMirabilis2_Leg1_43_AKS302 (iMirabilis2 station 43) * Latitude: 14.721900 * Longitude: -25.175500 * Date/Time: 2021-08-15T00:00:00 * Elevation: -4197.0 m * Location: NW-Africa, Cabo Verde Abyssal Plain * Campaign: iMirabilis2_Leg1 * Basis: Sarmiento de Gamboa * Method/Device: Benthic chamber lander (BCL) * Comment: One experimental chamber, two background chambers.
Parameter(s):
#NameShort NameUnitPrincipal InvestigatorMethod/DeviceComment
1Event labelEventSweetman, Andrew K
2Type of studyStudy typeSweetman, Andrew K
3LATITUDELatitudeSweetman, Andrew KBottom lander, chamber (BL_C)Geocode
4LONGITUDELongitudeSweetman, Andrew KBottom lander, chamber (BL_C)Geocode
5Sample elevationElevationmSweetman, Andrew KBottom lander, chamber (BL_C)
6Date/time start, experimentDate/time start expSweetman, Andrew KBottom lander, chamber (BL_C)Corresponds to the UTC date and time when the incubation occurred, where fully extended chambers into sediment is T0 and fully retracted chambers out of sediment is T48.
7Date/time end, experimentDate/time end expSweetman, Andrew KBottom lander, chamber (BL_C)Corresponds to the UTC date and time when the incubation occurred, where fully extended chambers into sediment is T0 and fully retracted chambers out of sediment is T48.
8Experiment durationExp durationhSweetman, Andrew KCorresponds to the UTC date and time when the incubation occurred, where fully extended chambers into sediment is T0 and fully retracted chambers out of sediment is T48.
9Chamber numberChamber noSweetman, Andrew KBottom lander, chamber (BL_C)Chamber identifier on the benthic lander.
10TreatmentTreatSweetman, Andrew KBottom lander, chamber (BL_C)Stable isotope tracer experiment or background (control) treatment.
11TracerTracerSweetman, Andrew KBottom lander, chamber (BL_C)Description of injection substrate.
12Tracer injectionTracer injectionmgSweetman, Andrew KBottom lander, chamber (BL_C)Mass of injected material.
13Carbon, per dry massC/dm%Sweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Tracer; Analyzed at UC Davis, Stable Isotope Facility (California, USA).
14Nitrogen, per dry massN/dm%Sweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Tracer; Analyzed at UC Davis, Stable Isotope Facility (California, USA).
15Atom percent, 13CAt perc 13C%Sweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Tracer; Analyzed at UC Davis, Stable Isotope Facility (California, USA). Standard: VPDB (R = 0.0111802).
16Atom percent, 15NAt perc 15N%Sweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Tracer: Analyzed at UC Davis, Stable Isotope Facility (California, USA). Standard: air (R = 0.0036782).
17Tracer injectionTracer injectiong/m2Sweetman, Andrew K
18HeightHeightmSweetman, Andrew KRuler stick (RULER)Water, chamber corner 1; Height of overlying water in corner 1 of the chamber.
19HeightHeightmSweetman, Andrew KRuler stick (RULER)Water, chamber corner 2; Height of overlying water in corner 2 of the chamber.
20HeightHeightmSweetman, Andrew KRuler stick (RULER)Water, chamber corner 3; Height of overlying water in corner 3 of the chamber.
21HeightHeightmSweetman, Andrew KRuler stick (RULER)Water, chamber corner 4; Height of overlying water in corner 4 of the chamber.
22Surface areaSAcm2Sweetman, Andrew KRuler stick (RULER)Chamber; Surface area of incubated sediments in chamber.
23Chamber volumeChamber vollSweetman, Andrew KWater; Volume of overlying water in the chamber, based on the average height of overlying water and the surface area.
24Serial numberSer NoSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode; Corresponds to raw optode datasets.
25Method commentMethod commSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode successful; If data was collected by the optode.
26Oxygen, dissolvedDOmg/lSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode; Processed oxygen concentration at T0 as measured with the optode.
27Date/time startDate/time startSweetman, Andrew KOxygen optode, Aanderaa type 4330FSCOC window; IMPORTANT! Not UTC. Optode time stamp was changed to UTC only for deployment AKS306 and AKS309. Start of measuring interval used for Sediment Community Oxygen Consumption (SCOC) regression, corresponding to time stamps in optode processed data file.
28Date/time endDate/time endSweetman, Andrew KOxygen optode, Aanderaa type 4330FSCOC window; IMPORTANT! Not UTC. Optode time stamp was changed to UTC only for deployment AKS306 and AKS309. End of measuring interval used for Sediment Community Oxygen Consumption (SCOC) regression, corresponding to time stamps in optode processed data file.
29Oxygen consumption rateO2 conmmol/m3/hSweetman, Andrew KOxygen optode, Aanderaa type 4330FSediment Community, Optode; Sediment Community Oxygen Consumption (SCOC) based on processed optode measurements and linear regression.
30Oxygen, flux, sediment oxygen demandSODmmol/m2/daySweetman, Andrew KOxygen optode, Aanderaa type 4330FSediment Community, Optode; Sediment Community Oxygen Consumption (SCOC) based on processed optode measurements, linear regression, water volume, and experiment duration.
31Method commentMethod commSweetman, Andrew KBottom lander, chamber (BL_C)Water samples successful; If water samples were collected successfully at T0.33, T2, T10, T19, T28, T37, and T46.
32Oxygen, flux, sediment oxygen demandSODmmol/m2/daySweetman, Andrew KMicro-Winkler TitrationSediment Community, Winkler; Sediment Community Oxygen Consumption (SCOC) based on Micro-Winkler Titration, linear regression, water volume, and experiment duration.
33Community diel dissolved inorganic carbon, flux, totalComm DIC flux tmmol/m2/daySweetman, Andrew KDIC analyzer, Apollo SciTech, AS-C5 DIC Analyzer; Elemental Analyzer Isotope Ratio Mass Spectrometer (EA-IRMS), THERMO, Flash 1112 DELTA-VTracer derived; Dissolved Inorganic Carbon (DIC) production rate calculated from DIC concentration, DI13C, regression, water volume, chamber surface, seawater density, and algae 13C labeling.
34Ammonium[NH4]+µmol/lSweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroConcentration in control water sample (T0.33).
35Nitrite[NO2]-µmol/lSweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroConcentration in control water sample (T0.33).
36Nitrate[NO3]-µmol/lSweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroConcentration in control water sample (T0.33).
37Phosphate[PO4]3-µmol/lSweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroConcentration in control water sample (T0.33).
38SilicateSi(OH)4µmol/lSweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroConcentration in control water sample (T0.33).
39Ammonium, flux[NH4]+ fluxµmol/m2/daySweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroNet concentration change from T0.33 to T46, adjusted for sediment surface, water volume, and experiment duration. Positive values mean a sediment efflux, negative values mean a sediment influx.
40Nitrite, flux[NO2]- fluxµmol/m2/daySweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroNet concentration change from T0.33 to T46, adjusted for sediment surface, water volume, and experiment duration. Positive values mean a sediment efflux, negative values mean a sediment influx.
41Nitrate, flux[NO3]- fluxµmol/m2/daySweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroNet concentration change from T0.33 to T46, adjusted for sediment surface, water volume, and experiment duration. Positive values mean a sediment efflux, negative values mean a sediment influx.
42Phosphate, flux[PO4]3- fluxµmol/m2/daySweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroNet concentration change from T0.33 to T46, adjusted for sediment surface, water volume, and experiment duration. Positive values mean a sediment efflux, negative values mean a sediment influx.
43Silicate, fluxSi(OH)4 fluxµmol/m2/daySweetman, Andrew KSegmented continuous flow analyzer, SEAL Analytical, QuAAtroNet concentration change from T0.33 to T46, adjusted for sediment surface, water volume, and experiment duration. Positive values mean a sediment efflux, negative values mean a sediment influx.
44Carbon, per dry massC/dm%Sweetman, Andrew KElemental Analyzer coupled to an Isotope Ratio Mass Spectrometer (EA-IRMS)Total Organic Carbon (TOC), Sediment; 0-5 cm horizon.
45Carbon, organic, totalTOCg/m2Sweetman, Andrew KElemental Analyzer coupled to an Isotope Ratio Mass Spectrometer (EA-IRMS)Sediment; 0-5 cm horizon.
46BiomarkerBiomarkerSweetman, Andrew KPhospholipid-derived Fatty Acid (PLFA) extraction followed by Gas Chromatography Isotope Ratio Mass Spectrometry (GC-IRMS)Phospholipid-derived Fatty Acids (PLFA) biomarkers used for bacterial biomass and C uptake.
47Bacteria, biomass as carbonBact Cg/m2Sweetman, Andrew KPhospholipid-derived Fatty Acid (PLFA) extraction followed by Gas Chromatography Isotope Ratio Mass Spectrometry (GC-IRMS)Bacterial biomass for 0-5 cm sediment depth estimated from PLFA data, average PLFA concentration in bacterial cells, sediment dry bulk density, sediment porosity, and chamber surface area.
48Bacteria, incorporation rate of carbonBact inc Cmg/m2/daySweetman, Andrew KPhospholipid-derived Fatty Acid (PLFA) extraction followed by Gas Chromatography Isotope Ratio Mass Spectrometry (GC-IRMS)Bacterial substrate-derived C incorporation for 0-5 cm sediment depth estimated from PLFA data, average PLFA concentration in bacterial cells, sediment dry bulk density, sediment porosity, substrate tracer labelling, chamber surface area, and duration of the experiment.
49NematodaNematoda#/10 cm2Sweetman, Andrew KLUDOX density separation using 32 um sieve modified from Rohal et al. 2018Density for 0-5 cm sediment horizon. Excluding Foraminifera.
50MeiobenthosMeiob#/m2Sweetman, Andrew KLUDOX density separation using 32 um sieve modified from Rohal et al. 2018other meiobenthos; Density for 0-5 cm sediment horizon. Excluding Foraminifera.
51MeiobenthosMeiob#/m2Sweetman, Andrew KLUDOX density separation using 32 um sieve modified from Rohal et al. 2018all meiobenthos; Density for 0-5 cm sediment horizon. Excluding Foraminifera.
52Meiobenthos, biomassMeiob biommg/m2Sweetman, Andrew KOven-driedDry mass; 45°C; Biomass for 0-5 cm sediment horizon. Excluding Foraminifera.
53Meiobenthos, biomass as carbonMeiob Cµg/cm2Sweetman, Andrew KElemental analyzer, Thermo Fisher Scientific, FlashEA 1112; coupled with Continuous flow isotope ratio mass spectrometer, Thermo Fisher Scientific, Delta Plus XPBiomass for 0-5 cm sediment horizon. Excluding Foraminifera.
54Meiobenthos, biomass as nitrogenMeiob Nµg/cm2Sweetman, Andrew KElemental analyzer, Thermo Fisher Scientific, FlashEA 1112; coupled with Continuous flow isotope ratio mass spectrometer, Thermo Fisher Scientific, Delta Plus XPNitrogen; Biomass for 0-5 cm sediment horizon. Excluding Foraminifera.
55Meiobenthos, incorporation rate of carbonMeiob inc Cµg/m2/daySweetman, Andrew KElemental analyzer, Thermo Fisher Scientific, FlashEA 1112; coupled with Continuous flow isotope ratio mass spectrometer, Thermo Fisher Scientific, Delta Plus XPIncorporation by meiobenthos for the 0-5 cm sediment horizon, using algae labelling, surface area, and experiment duration. Excluding Foraminifera.
56Meiobenthos, incorporation rate of nitrogenMeiob inc Nµg/m2/daySweetman, Andrew KElemental analyzer, Thermo Fisher Scientific, FlashEA 1112; coupled with Continuous flow isotope ratio mass spectrometer, Thermo Fisher Scientific, Delta Plus XPIncorporation by meiobenthos for the 0-5 cm sediment horizon, using algae labelling, surface area, and experiment duration. Excluding Foraminifera.
57Macrofauna, abundanceMacrof abund#/m2Sweetman, Andrew KSieve, retained on 300 um sieve.Macrofauna in the 0-5 cm sediment horizon.
58Macrofauna, biomass, per dry massMacrof biom/dmmg/m2Sweetman, Andrew KOven-dried45°C; Macrofauna in the 0-5 cm sediment horizon.
59Macrofauna, biomass as carbonMacrof Cg/m2Sweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Macrofauna in the 0-5 cm sediment horizon. Raw values for 0-10 cm adjusted to 0-5 cm by the same fraction as the fraction dry mass in the 5-10 cm layer, if needed.
60Macrofauna, biomass as nitrogenMacrof biom Nmg/m2Sweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Macrofauna in the 0-5 cm sediment horizon. Raw values for 0-10 cm adjusted to 0-5 cm by the same fraction as the fraction dry mass in the 5-10 cm layer, if needed.
61Macrofauna, incorporation rate of carbonMacrof inc Cµg/m2/daySweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Incorporation by macrofauna in the 0-5 cm sediment horizon (adjusted based on biomass distribution from 0-10 if needed), using algae labelling, surface area, and experiment duration.
62Macrofauna, incorporation rate of nitrogenMacrof inc Nµg/m2/daySweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Incorporation by macrofauna in the 0-5 cm sediment horizon (adjusted based on biomass distribution from 0-10 if needed), using algae labelling, surface area, and experiment duration.
63Foraminifera, benthic, biomassForam benth biommg/m2Sweetman, Andrew KOven dried at 45°C, followed by conversion from inorganic to organic biomass (= 0.05)Dry mass; Estimated from pre-acidification biomass using the conversion factor.
64Foraminifera, biomass as carbonForam Cmg/m2Sweetman, Andrew KConversion from organic biomass to C content ( = 0.01) according to A. Sweetman (unpublished data)Estimated from organic biomass using the conversion factor.
65Foraminifera, benthic, incorporation rate of carbonForam benth inc Cµg/m2/daySweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Incorporation by >300 um Foraminifera for the 0-5 cm sediment horizon, using algae labelling, surface area, and experiment duration.
66Foraminifera, benthic, incorporation rate of nitrogenForam benth inc Nµg/m2/daySweetman, Andrew KElemental Analyzer, Langenselbold, Germany, Elementar vario MICRO cube; coupled with Isotope Ratio Mass Spectrometer, Sercon, Europa 20-20Incorporation by >300 um Foraminifera for the 0-5 cm sediment horizon, using algae labelling, surface area, and experiment duration.
67Binary ObjectBinarySweetman, Andrew KDIC analyzer, Apollo SciTech, AS-C5 DIC Analyzer; Elemental Analyzer Isotope Ratio Mass Spectrometer (EA-IRMS), THERMO, Flash 1112 DELTA-VDIC data
68Binary Object (Media Type)Binary (Type)Sweetman, Andrew KDIC analyzer, Apollo SciTech, AS-C5 DIC Analyzer; Elemental Analyzer Isotope Ratio Mass Spectrometer (EA-IRMS), THERMO, Flash 1112 DELTA-VDIC data
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76Binary ObjectBinarySweetman, Andrew KPhospholipid-derived Fatty Acid (PLFA) extraction followed by Gas Chromatography Isotope Ratio Mass Spectrometry (GC-IRMS)PLFA data
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94Binary ObjectBinarySweetman, Andrew KAlgae Isotope Tracer
95Binary Object (Media Type)Binary (Type)Sweetman, Andrew KAlgae Isotope Tracer
96Binary Object (File Size)Binary (Size)BytesSweetman, Andrew KAlgae Isotope Tracer
97Binary ObjectBinarySweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode factory calibration
98Binary Object (Media Type)Binary (Type)Sweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode factory calibration
99Binary Object (File Size)Binary (Size)BytesSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode factory calibration
100Binary ObjectBinarySweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode calibration coefficients
101Binary Object (Media Type)Binary (Type)Sweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode calibration coefficients
102Binary Object (File Size)Binary (Size)BytesSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode calibration coefficients
103Binary ObjectBinarySweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode recalibration points
104Binary Object (Media Type)Binary (Type)Sweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode recalibration points
105Binary Object (File Size)Binary (Size)BytesSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode recalibration points
106Binary ObjectBinarySweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode unprocessed data
107Binary Object (Media Type)Binary (Type)Sweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode unprocessed data
108Binary Object (File Size)Binary (Size)BytesSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode unprocessed data
109Binary ObjectBinarySweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode processed data
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111Binary Object (File Size)Binary (Size)BytesSweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode processed data
112Linear regression equationLRESweetman, Andrew KOxygen optode, Aanderaa type 4330FOptode; Formula of linear regression through processed optode data points within the SCOC window, where cO2 is the oxygen concentration [uM] and T is the time [h].
113Linear regression equationLRESweetman, Andrew KOxygen optode, Aanderaa type 4330FR**2, Optode; Linear regression coefficient indicating fit of line.
114Binary ObjectBinarySweetman, Andrew KMicro-Winkler TitrationWinkler data
115Binary Object (Media Type)Binary (Type)Sweetman, Andrew KMicro-Winkler TitrationWinkler data
116Binary Object (File Size)Binary (Size)BytesSweetman, Andrew KMicro-Winkler TitrationWinkler data
117Linear regression equationLRESweetman, Andrew KMicro-Winkler TitrationWinkler; Formula of linear regression through mean Winkler data points, where cO2 is the oxygen concentration [uM] and T is the time [h].
118Linear regression equationLRESweetman, Andrew KMicro-Winkler TitrationR**2, Winkler; Linear regression coefficient indicating fit of line.
119Linear regression equationLRESweetman, Andrew KDIC analyzer, Apollo SciTech, AS-C5 DIC Analyzer; Elemental Analyzer Isotope Ratio Mass Spectrometer (EA-IRMS), THERMO, Flash 1112 DELTA-VDIC; Formula of linear regression through DIC data points, where cDIC is the DIC concentration [mg C m-2] and T is the time [h].
120Linear regression equationLRESweetman, Andrew KDIC analyzer, Apollo SciTech, AS-C5 DIC Analyzer; Elemental Analyzer Isotope Ratio Mass Spectrometer (EA-IRMS), THERMO, Flash 1112 DELTA-VR**2, DIC; Linear regression coefficient indicating fit of line.
License:
Creative Commons Attribution 4.0 International (CC-BY-4.0)
Status:
Curation Level: Enhanced curation (CurationLevelC) * Processing Level: PANGAEA data processing level 3 (ProcLevel3)
Size:
757 data points

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