de Jonge, Danielle; Gaurisas, Daniela Y; Bernardino, Angelo Fraga; Sweetman, Andrew K (2025): Sediment fluxes from stable isotope tracer incubation experiments under climate change projections in the Cabo Verde Basin, NE Atlantic [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.984058, In: de Jonge, D et al. (2025): Sediment fluxes and biotic C cycling from stable isotope tracer incubation experiments under climate change projections in the Cabo Verde Basin, NE Atlantic [dataset bundled publication]. PANGAEA, https://doi.org/10.1594/PANGAEA.984021
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Published: 2025-09-16 • DOI registered: 2025-10-15
Abstract:
An experimental approach was developed to assess the individual and combined effects of two climate change stressors (temperature and POC quality) on soft sediments in the bathyal continental margin of the Cabo Verde Basin (CVB, Equatorial Atlantic). The study used stable isotope tracer incubation experiments with 13C and 15N labelled diatoms Phaeodactylum tricornutum, to simulate climate change projections for the next century. A balanced experimental design was employed to examine the impacts of increased temperature (+2 °C), reduced POC quality (dialysed labile fraction), or both, compared to a control treatment. The experiments were carried out onboard the research vessel Sarmiento de Gamboa during the iMirabilis2 campaign in August 2021 (Orejas et al., 2022). A total of 19 sediment samples were collected by four multi-corer (MUC) deployments. From each MUC deployment, four cores with clear overlying water were randomly selected and assigned among the four different treatments (total n= 4 for each of 4 treatments), and the remaining three cores were used as background for natural stable isotopes. The upper 15-18 cm of sediment from each core was extruded to an incubation core (inner diameter 10 cm) closed airtight at the bottom. The incubation cores were placed in buckets with filtered seawater at the experimental temperature. After an equilibration period of 147 to 173 hours, the stable isotope experiment began with the injection of 12.5 mg of fresh or partially degraded diatoms into each core, representing approximately 10% of the average annual POC flux for the region (Sweetman et al., 2017). The experiment lasted 48 hours after the algae injection, with the cores maintained under constant aeration. During the incubation, Sediment Community Oxygen Consumption (SCOC) rates and DI13C production rates were measured twice (at T10 and at T45). At the experiment's conclusion, sediment samples were stored at -80°C for Phospho Lipid derived Fatty Acid (PLFA) analysis or fixed in 10% borax-buffered formalin seawater for macrofauna analysis (Gaurisas et al. 2024). Phospho Lipid derived Fatty Acid (PLFA) extraction according to Shahbaz et al. (2020) followed by Gas Chromatography Isotope Ratio Mass Spectrometry (GC-IRMS) according to Thornton et al. (2011), utilising bacterial biomarker C15:0i and related biomarker-specific fraction (7.4%) from Rajendran et al. (1993). Followed by adjustment for sediment Dry Bulk Density (DBD = 2.50 g cm-3) and sediment porosity (= 0.61) according to Thiede et al. (1982); followed by adjustment for bacterial-cell specific PLFA concentration (= 0.056 g C PLFA g-1 C) according to Brinch-Iversen & King (1990).
Keyword(s):
Related to:
Brinch-Iversen, J; King, Gary M (1990): Effects of substrate concentration, growth state, and oxygen availability on relationships among bacterial carbon, nitrogen and phospholipid phosphorus content*. FEMS Microbiology Ecology, 7(4), 345-355, https://doi.org/10.1111/j.1574-6941.1990.tb01701.x
Gaurisas, Daniela Y; de Jonge, Danielle; Sweetman, Andrew K; Bernardino, Angelo Fraga (2024): Effects of increased temperature and altered POC composition on a bathyal macrofaunal community in Cabo Verde, NE Atlantic. Progress in Oceanography, 229, 103352, https://doi.org/10.1016/j.pocean.2024.103352
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, 342, https://doi.org/10.5281/zenodo.6352141
Rajendran, Narasimmalu; Suwa, Yuichi; Urushigawa, Yoshikuni (1993): Distribution of phospholipid ester-linked fatty acid biomarkers for bacteria in the sediment of Ise Bay, Japan. Marine Chemistry, 42(1), 39-56, https://doi.org/10.1016/0304-4203(93)90248-M
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
Sweetman, Andrew K; Thurber, Andrew R; Smith, Craig R; Levin, Lisa A; Mora, Camilo; Wei, Chih-Lin; Gooday, Andrew J; Jones, Daniel O B; Rex, Michael A; Yasuhara, Moriaki; Ingels, Jeroen; Ruhl, Henry A; Frieder, Christina A; Danovaro, Roberto; Würzberg, Laura; Baco, Amy R; Grupe, Benjamin; Pasulka, Alexis L.; Meyer, Kristin; Dunlop, Katherine; Henry, Lea-Anne; Roberts, J Murray (2017): Major impacts of climate change on deep-sea benthic ecosystems. Elementa - Science of the Anthropocene, 5, 4, https://doi.org/10.1525/elementa.203
Thiede, Jörn; Suess, Erwin; Müller, Peter J (1982): Late Quaternary fluxes of major sediment components to the sea floor at the northwest African continental slope. in: von Rad, U; Hinz, K; Sarnthein, M & Seibold, E (eds.), Geology of the Northwest African Continental Margin, Springer-Verlag, Berlin, 605-631, https://doi.org/10.1007/978-3-642-68409-8_25
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
References:
Gaurisas, Daniela Y; de Jonge, Danielle; Bernardino, Angelo Fraga; Sweetman, Andrew K (2025): Bathyal benthic macrofauna composition, biomass, and carbon and nitrogen uptake from incubation experiments under climate change projections in the Cabo Verde Basin, NE Atlantic [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.977643
Project(s):
Funding:
Fundação de Amparo à Pesquisa do estado do Espírito Santo (FAPES), grant/award no. 85501689: Scholarship
Horizon 2020 (H2020), grant/award no. 818123: Integrated Assessment of Atlantic Marine Ecosystems in Space and Time
Coverage:
Latitude: 15.316500 * Longitude: -23.369100
Date/Time Start: 2021-08-04T02:42:00 * Date/Time End: 2021-08-04T07:18:00
Minimum ELEVATION: -876 m a.s.l. * Maximum ELEVATION: -874 m a.s.l.
Event(s):
iMirabilis2_Leg1_3_AKS291 (iMirabilis2 station 3) * Latitude: 15.316500 * Longitude: -23.369100 * Date/Time Start: 2021-08-04T02:42:00 * Date/Time End: 2021-08-04T03:33:00 * Elevation: -874.0 m * Location: Cabo Verde Archipelago, Cabo Verde * Campaign: iMirabilis2_Leg1 * Basis: Sarmiento de Gamboa * Method/Device: MultiCorer (MUC) * Comment: 5 successful cores out of 6
iMirabilis2_Leg1_4_AKS292 (iMirabilis2 station 4) * Latitude: 15.316500 * Longitude: -23.369100 * Date/Time Start: 2021-08-04T04:21:00 * Date/Time End: 2021-08-04T05:06:00 * Elevation: -876.0 m * Location: Cabo Verde Archipelago, Cabo Verde * Campaign: iMirabilis2_Leg1 * Basis: Sarmiento de Gamboa * Method/Device: MultiCorer (MUC) * Comment: 6 successful cores out of 6
iMirabilis2_Leg1_5_AKS293 (iMirabilis2 station 5) * Latitude: 15.316500 * Longitude: -23.369100 * Date/Time Start: 2021-08-04T05:23:00 * Date/Time End: 2021-08-04T06:07:00 * Elevation: -876.0 m * Location: Cabo Verde Archipelago, Cabo Verde * Campaign: iMirabilis2_Leg1 * Basis: Sarmiento de Gamboa * Method/Device: MultiCorer (MUC) * Comment: 6 successful cores out of 6
Parameter(s):
| # | Name | Short Name | Unit | Principal Investigator | Method/Device | Comment |
|---|---|---|---|---|---|---|
| 1 | Event label | Event | Sweetman, Andrew K | |||
| 2 | Order | Order | Sweetman, Andrew K | |||
| 3 | Type of study | Study type | Sweetman, Andrew K | |||
| 4 | LATITUDE | Latitude | Sweetman, Andrew K | Geocode | ||
| 5 | LONGITUDE | Longitude | Sweetman, Andrew K | Geocode | ||
| 6 | ELEVATION | Elevation | m a.s.l. | Sweetman, Andrew K | Geocode | |
| 7 | Core | Core | Sweetman, Andrew K | LMS-cooled incubators, model 300W [series 3, 290 L] | Core identifier | |
| 8 | Date/time start, experiment | Date/time start exp | Sweetman, Andrew K | LMS-cooled incubators, model 300W [series 3, 290 L] | Corresponds to the UTC date and time when the incubation started i.e. injection of substrate (T0) | |
| 9 | Date/time end, experiment | Date/time end exp | Sweetman, Andrew K | LMS-cooled incubators, model 300W [series 3, 290 L] | Corresponds to the UTC date and time when the incubation stopped i.e. core was processed | |
| 10 | Experiment duration | Exp duration | h | Sweetman, Andrew K | LMS-cooled incubators, model 300W [series 3, 290 L] | Duration of incubation, where injection of substrate is T0 and the start of core processing is the end of the incubation |
| 11 | Treatment | Treat | Sweetman, Andrew K | LMS-cooled incubators, model 300W [series 3, 290 L] | Treatment 1-4, with Treatment 1: control temperature (6.5 °C) and untreated algae injection; Treatment 2: elevated temperature (8.5 °C) and untreated algae injection; Treatment 3: control temperature (6.5 °C) and dialyzed algae injection, Treatment 4: elevated temperature (8.5 °C) and dialyzed algae injection | |
| 12 | Incubation temperature | Inc Temp | °C | Sweetman, Andrew K | LMS-cooled incubators, model 300W [series 3, 290 L] | Temperature setting of the incubator |
| 13 | Tracer injection | Tracer injection | Sweetman, Andrew K | Injection | Description of injected substrate; Substrate hydrated in 0.2 uM filtered seawater at temperature of incubator and injected to core overlying water using syringes | |
| 14 | Tracer injection | Tracer injection | mg | Sweetman, Andrew K | Injection | Mass of injected material; Substrate hydrated in 0.2 uM filtered seawater at temperature of incubator and injected to core overlying water using syringes; Substrate hydrated in 0.2 uM filtered seawater at temperature of incubator and injected to core overlying water using syringes. |
| 15 | Tracer injection | Tracer injection | g/m2 | Sweetman, Andrew K | Injection | Mass of injected material; Substrate hydrated in 0.2 uM filtered seawater at temperature of incubator and injected to core overlying water using syringes. Substrate C content was 26.6±6.7 DM wt% |
| 16 | Surface area | SA | cm2 | Sweetman, Andrew K | Surface area of incubated sediments in core | |
| 17 | Height | Height | m | Sweetman, Andrew K | Ruler stick (RULER) | Resolution 0.005m (0.5 cm); Height of incubated sediment |
| 18 | Chamber volume | Chamber vol | l | Sweetman, Andrew K | Volumetry | Measuring cylinder; Resolution 0.005 L; Volume of overlying water in the chamber, based on the average height of overlying water and the surface area |
| 19 | Time point, descriptive | Time point | Sweetman, Andrew K | Oxygen optode, Firesting | ID of the Sediment Community Oxygen Consumption (SCOC) window, either T10 or T45. During the SCOC window the cores were sealed. This happened twice, the first window ending around T10 and the second window ending around T45; During the Sediment Community Oxygen Consumption (SCOC) window the cores were sealed to allow flux measurements | |
| 20 | Duration | Duration | h | Sweetman, Andrew K | Oxygen optode, Firesting | Duration of the Sediment Community Oxygen Consumption (SCOC) measurement window; During the Sediment Community Oxygen Consumption (SCOC) window the cores were sealed to allow flux measurements |
| 21 | Time in hours | Time h | h | Sweetman, Andrew K | Oxygen optode, Firesting | End time of the Sediment Community Oxygen Consumption (SCOC) measurement window, with time relative to T0 i.e. relative to the start of incubation; During the Sediment Community Oxygen Consumption (SCOC) window the cores were sealed to allow flux measurements |
| 22 | Oxygen, flux, sediment oxygen demand | SOD | mmol/m2/day | Sweetman, Andrew K | Oxygen optode, Firesting | Sediment Community Oxygen Consumption (SCOC) based on processed optode measurements, linear regression, sediment surface area, and water volume |
| 23 | Community diel dissolved inorganic carbon, flux, total | Comm DIC flux t | mmol/m2/day | Sweetman, Andrew K | DIC analyzer, Apollo SciTech, AS-C5 DIC Analyzer; Elemental Analyzer Isotope Ratio Mass Spectrometer (EA-IRMS), THERMO, Flash 1112 DELTA-V | Dissolved Inorganic Carbon (DIC) production rate calculated from DIC concentration, DI13C, regression, water volume, core surface, seawater density (1035 g/L), and algae 13C labeling (13C = 14.9±3.0 atom-%) |
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:
606 data points