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Fuhr, Michael; Wallmann, Klaus; Dale, Andy W; Diercks, Isabel; Kalapurakkal, Habeeb Thanveer; Schmidt, Mark; Sommer, Stefan; Böhnke-Brandt, Stefanie; Perner, Mirjam; Geilert, Sonja: Major and trace elements during laboratory incubation experiments on natural benthic weathering in organic rich Baltic Sea sediments [dataset]. PANGAEA, https://doi.pangaea.de/10.1594/PANGAEA.974078 (dataset in review), In: Fuhr, M et al.: Experimental data on natural benthic weathering in organic rich Baltic Sea sediments [dataset bundled publication]. PANGAEA, https://doi.pangaea.de/10.1594/PANGAEA.974076 (dataset in review)

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Abstract:
Enhanced mineral dissolution in the benthic environment is currently discussed as a potential technique for ocean alkalinity enhancement (OAE) to reduce atmospheric CO2 levels. This study explores how biogeochemical processes affect the dissolution of alkaline minerals in surface sediments during laboratory incubation experiments. These involved introducing dunite and calcite to organic-rich sediments from the Baltic Sea under controlled conditions in an oxic environment. The sediment cores were incubated with Baltic Sea bottom water. Eight sediment cores were placed in a rack in an upright position. The bottom water was carefully removed via suction and replaced with a known volume (1.5 l – 2.0 l) of filtered (0.2 µm) Baltic Sea bottom water in order to remove pelagic auto- and heterotrophs and suspended particles. The volume of water added depended on the height of sediment in each core which varied slightly due to the recovery method. After this procedure, a gaseous headspace of ca. 10 cm was left in each core. Furthermore, the cores were equipped with adjustable stirring heads that contained ports for inserting optodes to continuously record pH and O2 concentrations in the overlying water. In order to prevent anoxic conditions developing, ambient air was bubbled into the water column. The water column in each core was slowly and continuously flushed with a constant throughflow of 40 µl min-1 from a single reservoir of bottom water. The residence time of the water inside the cores was thus about 4 to 5 weeks. Bottom water samples were taken from the outflow of each core over a time period of several hours. Thus, samples represent the average outflow over the respective time period. Sampling intervals increased from daily during the first two weeks to every three to four days and weekly towards the end of the experiment. All samples were filtered through a 0.2 µm cellulose membrane filter and refrigerated in 25 ml ZinsserTM scintillation vials. A 5 ml aliquot was frozen directly after the sampling procedure for later nutrient analysis. Nutrient measurements were performed either via manual photometric measurement (NH4) or using a Seal – AnalyticalTM QuAAtro autoanalyzer (PO43-, NO2-, NO3-). Samples for TA were analyzed directly after sampling by titration of 1 ml of bottom/pore water with 0.02N HCl. Titration was ended when a stable purple color appeared. During titration, the sample was degassed by continuous bubbling with nitrogen to remove any generated CO2 and H2S. The acid was standardized using an IAPSO seawater standard. Anion element concentrations (SO42-, Cl-, Br-) were determined using ion chromatography (IC, METROHM 761 Compact, conductivity mode). Acidified sub-samples (30 μl suprapure HNO3- + 3 ml sample) were prepared for analyses of major and trace elements (Si, Na, K, Li, B, Mg, Ca, Sr, Mn, Ni and Fe) by inductively coupled plasma optical emission spectroscopy (ICP-OES, Varian 720-ES). At the end of the experiments, the bottom water was removed via suction and the cores were sliced for pore water analysis. The pore waters were recovered by centrifuging each respective sediment layer in 50 ml falcon tubes at 3000 rpm for 10 minutes. Afterwards, the supernatant water was transferred to polyethylene (PE) vials in an Ar-filled glove bag to minimize contact with oxygen. In addition to the parameters listed above, pore waters were analyzed for H2S and Fe2+. For the analysis of dissolved Fe2+ concentrations, sub-samples of 1 ml were taken within the glove bag, immediately stabilized with ascorbic acid and analyzed within 30 minutes after complexation with 20 μl of Ferrozin. For H2S, an aliquot of pore water was diluted with appropriate amounts of oxygen-free artificial seawater and the H2S was fixed by immediate addition of zinc acetate gelatin solution.
Keyword(s):
calcite dissolution; dunite dissolution; enhanced weathering; incubation experiment; Laboratory experiment
Supplement to:
Fuhr, Michael; Wallmann, Klaus; Dale, Andrew W; Diercks, Isabel; Kalapurakkal, Habeeb Thanveer; Schmidt, Mark; Sommer, Stefan; Böhnke, Stefanie; Perner, Mirjam; Geilert, Sonja (2023): Disentangling artificial and natural benthic weathering in organic rich Baltic Sea sediments. Frontiers in Climate, 5, 1245580, https://doi.org/10.3389/fclim.2023.1245580
Funding:
Federal Ministry of Education and Research (BMBF), grant/award no. 03F0895A: DAM CDRmare - RETAKE, GEOMAR
Coverage:
Latitude: 54.516670 * Longitude: 10.041670
Date/Time Start: 2022-01-22T00:00:00 * Date/Time End: 2022-01-22T00:00:00
Minimum Elevation: -27.0 m * Maximum Elevation: -27.0 m
Event(s):
L22_core * Latitude: 54.516670 * Longitude: 10.041670 * Date/Time: 2022-01-22T00:00:00 * Elevation: -27.0 m * Location: Boknis Eck * Campaign: L22_daytrip * Basis: Littorina * Method/Device: Sediment corer (SEDCO) * Comment: Original sampling location of tested surface sediments; salinity: 21; water temperature: 4.2 °C
Parameter(s):
#NameShort NameUnitPrincipal InvestigatorMethod/DeviceComment
1Type of studyStudy typeGeilert, Sonja
2Sample typeSamp typeGeilert, Sonja
3TreatmentTreatGeilert, Sonja
4Sample IDSample IDGeilert, SonjaM1=Cal1, M2=Cal2, M3=Cal3, M4=Dun1, M5=Dun2, M6=Dun3, B1=C1, B2=C2
5Time in daysTimedaysGeilert, SonjaSmartphone application, Apple, Calendar [iPhone SE 2016]
6BoronBmmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
7Boron, standard deviationB std dev±Geilert, SonjaRelative standard deviation (RSD%)
8ManganeseMnµmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
9Manganese, standard deviationMn std dev±Geilert, SonjaRelative standard deviation (RSD%)
10CalciumCammol/lGeilert, SonjaICP-OES, VARIAN 720-ES
11Calcium, standard deviationCa std dev±Geilert, SonjaRelative standard deviation (RSD%)
12IronFeµmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
13Iron, standard deviationFe std dev±Geilert, SonjaRelative standard deviation (RSD%)
14SodiumNammol/lGeilert, SonjaICP-OES, VARIAN 720-ES
15Sodium, standard deviationNa std dev±Geilert, SonjaRelative standard deviation (RSD%)
16MagnesiumMgmmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
17Magnesium, standard deviationMg std dev±Geilert, SonjaRelative standard deviation (RSD%)
18StrontiumSrµmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
19Strontium, standard deviationSr std dev±Geilert, SonjaRelative standard deviation (RSD%)
20SiliconSimmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
21Silicon, standard deviationSi std dev±Geilert, SonjaRelative standard deviation (RSD%)
22BariumBanmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
23Barium, standard deviationBa std dev±Geilert, SonjaRelative standard deviation (RSD%)
24LithiumLiµmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
25Lithium, standard deviationLi std dev±Geilert, SonjaRelative standard deviation (RSD%)
26PotassiumKmmol/lGeilert, SonjaICP-OES, VARIAN 720-ES
27Potassium, standard deviationK std dev±Geilert, SonjaRelative standard deviation (RSD%)
License:
Creative Commons Attribution 4.0 International (CC-BY-4.0) (License comes into effect after moratorium ends)
Status:
Curation Level: Enhanced curation (CurationLevelC)
Size:
8370 data points

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