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(Table S4) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)

Ahrens, Janis ; Beck, Melanie ; Marchant, Hannah K ; [et al.]

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Publication Date: 2023-01-30

Keywords: ammonium; Ammonium; Calculated; Calculated: NOx - NO2; Calulated: NOx + NH4; Coastal section; Conductivity probe with integrated temperature sensor; CSEC; DATE/TIME; DEPTH, water; DGPS; estimated for North Beach Seawater; Event label; Flow through cell; optical measurement (PyroScience); High Energy Beach; iron; Iron; LATITUDE; LONGITUDE; manganese; Manganese; Mass spectrometry; nitrate; Nitrate; Nitrate and Nitrite; nitrite; Nitrite; Nitrogen, inorganic, dissolved; North Sea; Oxygen; Photometric; Salinity; Spiekeroog_S4_NBSW-01; Spiekeroog_S4_NBSW-02; Spiekeroog_S4_NBSW-03; Spiekeroog, German Bight, North Sea; Station label; subterranean estuary; Temperature, water; Transect; UTM Easting, Universal Transverse Mercator; UTM Northing, Universal Transverse Mercator

Type: Dataset

Format: text/tab-separated-values, 44 data points

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(Table S5) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)

Ahrens, Janis ; Beck, Melanie ; Marchant, Hannah K ; [et al.]

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Publication Date: 2023-01-30

Keywords: ammonium; Ammonium; Calculated: NOx - NO2; Coastal section; CSEC; DATE/TIME; DGPS; estimated for North Beach Seawater; Event label; High Energy Beach; iron; LATITUDE; LONGITUDE; manganese; nitrate; Nitrate; Nitrate and Nitrite; nitrite; Nitrite; North Sea; Photometric; Silicon; Spiekeroog_S5-01; Spiekeroog_S5-02; Spiekeroog_S5-03; Spiekeroog_S5-04; Spiekeroog_S5-05; Spiekeroog_S5-06; Spiekeroog_S5-07; Spiekeroog_S5-08; Spiekeroog_S5-09; Spiekeroog_S5-10; Spiekeroog_S5-11; Spiekeroog_S5-12; Spiekeroog_S5-13; Spiekeroog_S5-14; Spiekeroog_S5-15; Spiekeroog_S5-16; Spiekeroog_S5-17; Spiekeroog_S5-18; Spiekeroog_S5-19; Spiekeroog_S5-20; Spiekeroog_S5-21; Spiekeroog_S5-22; Spiekeroog_S5-23; Spiekeroog_S5-24; Spiekeroog_S5-25; Spiekeroog_S5-26; Spiekeroog_S5-27; Spiekeroog_S5-28; Spiekeroog_S5-29; Spiekeroog_S5-30; Spiekeroog_S5-31; Spiekeroog_S5-32; Spiekeroog_S5-33; Spiekeroog_S5-34; Spiekeroog_S5-35; Spiekeroog_S5-36; Spiekeroog_S5-37; Spiekeroog_S5-38; Spiekeroog_S5-39; Spiekeroog_S5-40; Spiekeroog_S5-41; Spiekeroog_S5-42; Spiekeroog_S5-43; Spiekeroog, German Bight, North Sea; Station label; subterranean estuary; UTM Easting, Universal Transverse Mercator; UTM Northing, Universal Transverse Mercator

Type: Dataset

Format: text/tab-separated-values, 391 data points

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(Table S3) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)

Ahrens, Janis ; Beck, Melanie ; Marchant, Hannah K ; [et al.]

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Publication Date: 2023-02-07

Keywords: ammonium; Ammonium; Calculated; Calculated: DGPS surface elevation - depth below sediment surface; Calculated: NOx - NO2; Calulated: NOx + NH4; Coastal section; Conductivity probe; Conductivity probe with integrated temperature sensor; CSEC; DATE/TIME; DEPTH, sediment/rock; DGPS; estimated for North Beach Seawater; ELEVATION; Event label; Flow through cell; optical measurement (PyroScience); High Energy Beach; iron; Iron; LATITUDE; LONGITUDE; manganese; Manganese; Mass spectrometry; nitrate; Nitrate; Nitrate and Nitrite; nitrite; Nitrite; Nitrogen, inorganic, dissolved; North Sea; Oxygen; Photometric; POINT DISTANCE from start; Salinity; Spiekeroog_S3_Grid100-401; Spiekeroog_S3_Grid100-403; Spiekeroog_S3_Grid100-405; Spiekeroog_S3_Grid100-407; Spiekeroog_S3_Grid100-409; Spiekeroog_S3_Grid100-411; Spiekeroog_S3_Grid100-413; Spiekeroog_S3_Grid100-415; Spiekeroog_S3_Grid100-417; Spiekeroog_S3_Grid100-419; Spiekeroog_S3_Grid100-421; Spiekeroog_S3_Grid100-427; Spiekeroog_S3_Grid100-428; Spiekeroog_S3_Grid100-443; Spiekeroog_S3_Grid100-445; Spiekeroog_S3_Grid100-447; Spiekeroog_S3_Grid100-449; Spiekeroog_S3_Grid100-451; Spiekeroog_S3_Grid100-453; Spiekeroog_S3_Grid100-455; Spiekeroog_S3_Grid100-457; Spiekeroog_S3_Grid100-459; Spiekeroog_S3_Grid100-461; Spiekeroog_S3_Grid100-463; Spiekeroog_S3_Grid100-485; Spiekeroog_S3_Grid100-487; Spiekeroog_S3_Grid100-489; Spiekeroog_S3_Grid100-491; Spiekeroog_S3_Grid100-493; Spiekeroog_S3_Grid100-495; Spiekeroog_S3_Grid100-504; Spiekeroog_S3_Grid100-506; Spiekeroog_S3_Grid100-508; Spiekeroog_S3_Grid100-509; Spiekeroog_S3_Grid100-510; Spiekeroog_S3_Grid100-511; Spiekeroog_S3_Grid100-512; Spiekeroog_S3_Grid100-514; Spiekeroog_S3_Grid100-516; Spiekeroog_S3_Grid100-517; Spiekeroog_S3_Grid100-518; Spiekeroog_S3_Grid100-519; Spiekeroog_S3_Grid100-520; Spiekeroog_S3_Grid100-521; Spiekeroog_S3_Grid100-522; Spiekeroog_S3_Grid100-523; Spiekeroog_S3_Grid100-524; Spiekeroog_S3_Grid100-525; Spiekeroog_S3_Grid100-526; Spiekeroog_S3_Grid100-527; Spiekeroog_S3_Grid100-528; Spiekeroog_S3_Grid100-529; Spiekeroog_S3_Grid100-530; Spiekeroog_S3_Grid100-531; Spiekeroog_S3_Grid100-532; Spiekeroog_S3_Grid100-533; Spiekeroog_S3_Grid100-534; Spiekeroog_S3_Grid100-535; Spiekeroog_S3_Grid100-536; Spiekeroog_S3_Grid100-537; Spiekeroog_S3_Grid100-538; Spiekeroog_S3_Grid100-539; Spiekeroog_S3_Grid100-540; Spiekeroog_S3_Grid100-541; Spiekeroog_S3_Grid100-542; Spiekeroog_S3_Grid100-543; Spiekeroog_S3_Grid100-544; Spiekeroog_S3_Grid100-545; Spiekeroog_S3_Grid100-546; Spiekeroog_S3_Grid100-547; Spiekeroog_S3_Grid100-548; Spiekeroog_S3_Grid100-552; Spiekeroog_S3_Grid100-553; Spiekeroog_S3_Grid100-554; Spiekeroog_S3_Grid100-555; Spiekeroog_S3_Grid100-556; Spiekeroog_S3_Grid100-557; Spiekeroog_S3_Grid100-558; Spiekeroog_S3_Grid100-559; Spiekeroog_S3_Grid100-560; Spiekeroog_S3_Grid100-561; Spiekeroog_S3_Grid100-562; Spiekeroog_S3_Grid100-563; Spiekeroog_S3_Grid100-564; Spiekeroog_S3_Grid100-565; Spiekeroog_S3_Grid100-567; Spiekeroog_S3_Grid100-568; Spiekeroog_S3_Grid100-569; Spiekeroog_S3_Grid100-570; Spiekeroog_S3_Grid100-571; Spiekeroog_S3_Grid100-572; Spiekeroog_S3_Grid100-573-1; Spiekeroog_S3_Grid100-573-2; Spiekeroog_S3_Grid100-574; Spiekeroog_S3_Grid100-575; Spiekeroog_S3_Grid100-576; Spiekeroog_S3_Grid100-577; Spiekeroog_S3_Grid100-578; Spiekeroog_S3_Grid100-579; Spiekeroog_S3_Grid100-580; Spiekeroog_S3_Grid100-581; Spiekeroog_S3_Grid100-582; Spiekeroog_S3_Grid100-583; Spiekeroog_S3_Grid100-584; Spiekeroog_S3_Grid100-585; Spiekeroog_S3_Grid100-586; Spiekeroog_S3_Grid100-587; Spiekeroog_S3_Grid100-588; Spiekeroog_S3_Grid100-589; Spiekeroog_S3_Grid100-590; Spiekeroog_S3_Grid100-599; Spiekeroog_S3_Grid50-401; Spiekeroog_S3_Grid50-403; Spiekeroog_S3_Grid50-405; Spiekeroog_S3_Grid50-407; Spiekeroog_S3_Grid50-409; Spiekeroog_S3_Grid50-411; Spiekeroog_S3_Grid50-413; Spiekeroog_S3_Grid50-415; Spiekeroog_S3_Grid50-417; Spiekeroog_S3_Grid50-419; Spiekeroog_S3_Grid50-421; Spiekeroog_S3_Grid50-427; Spiekeroog_S3_Grid50-428; Spiekeroog_S3_Grid50-443; Spiekeroog_S3_Grid50-445; Spiekeroog_S3_Grid50-447; Spiekeroog_S3_Grid50-449; Spiekeroog_S3_Grid50-451; Spiekeroog_S3_Grid50-453; Spiekeroog_S3_Grid50-455; Spiekeroog_S3_Grid50-457; Spiekeroog_S3_Grid50-459; Spiekeroog_S3_Grid50-461; Spiekeroog_S3_Grid50-463; Spiekeroog_S3_Grid50-485; Spiekeroog_S3_Grid50-487; Spiekeroog_S3_Grid50-489; Spiekeroog_S3_Grid50-491; Spiekeroog_S3_Grid50-493; Spiekeroog_S3_Grid50-495; Spiekeroog_S3_Grid50-504; Spiekeroog_S3_Grid50-506; Spiekeroog_S3_Grid50-508; Spiekeroog_S3_Grid50-509; Spiekeroog_S3_Grid50-510; Spiekeroog_S3_Grid50-511; Spiekeroog_S3_Grid50-512; Spiekeroog_S3_Grid50-514; Spiekeroog_S3_Grid50-516; Spiekeroog_S3_Grid50-517; Spiekeroog_S3_Grid50-518; Spiekeroog_S3_Grid50-519; Spiekeroog_S3_Grid50-520; Spiekeroog_S3_Grid50-521; Spiekeroog_S3_Grid50-522; Spiekeroog_S3_Grid50-523; Spiekeroog_S3_Grid50-524; Spiekeroog_S3_Grid50-525; Spiekeroog_S3_Grid50-526; Spiekeroog_S3_Grid50-527; Spiekeroog_S3_Grid50-528; Spiekeroog_S3_Grid50-529; Spiekeroog_S3_Grid50-530; Spiekeroog_S3_Grid50-531; Spiekeroog_S3_Grid50-532; Spiekeroog_S3_Grid50-533; Spiekeroog_S3_Grid50-534; Spiekeroog_S3_Grid50-535; Spiekeroog_S3_Grid50-536; Spiekeroog_S3_Grid50-537; Spiekeroog_S3_Grid50-538; Spiekeroog_S3_Grid50-539; Spiekeroog_S3_Grid50-540; Spiekeroog_S3_Grid50-541; Spiekeroog_S3_Grid50-542; Spiekeroog_S3_Grid50-543; Spiekeroog_S3_Grid50-544; Spiekeroog_S3_Grid50-545; Spiekeroog_S3_Grid50-546; Spiekeroog_S3_Grid50-547; Spiekeroog_S3_Grid50-548; Spiekeroog_S3_Grid50-552; Spiekeroog_S3_Grid50-553; Spiekeroog_S3_Grid50-554; Spiekeroog_S3_Grid50-555; Spiekeroog_S3_Grid50-556; Spiekeroog_S3_Grid50-557; Spiekeroog_S3_Grid50-558; Spiekeroog_S3_Grid50-559; Spiekeroog_S3_Grid50-560; Spiekeroog_S3_Grid50-561; Spiekeroog_S3_Grid50-562; Spiekeroog_S3_Grid50-563; Spiekeroog_S3_Grid50-564; Spiekeroog_S3_Grid50-565; Spiekeroog_S3_Grid50-567; Spiekeroog_S3_Grid50-568; Spiekeroog_S3_Grid50-569; Spiekeroog_S3_Grid50-570; Spiekeroog_S3_Grid50-571; Spiekeroog_S3_Grid50-572; Spiekeroog_S3_Grid50-573-1; Spiekeroog_S3_Grid50-573-2; Spiekeroog_S3_Grid50-574; Spiekeroog_S3_Grid50-575; Spiekeroog_S3_Grid50-576; Spiekeroog_S3_Grid50-577; Spiekeroog_S3_Grid50-578; Spiekeroog_S3_Grid50-579; Spiekeroog_S3_Grid50-580; Spiekeroog_S3_Grid50-581; Spiekeroog_S3_Grid50-582; Spiekeroog_S3_Grid50-583; Spiekeroog_S3_Grid50-584; Spiekeroog_S3_Grid50-585; Spiekeroog_S3_Grid50-586; Spiekeroog_S3_Grid50-587; Spiekeroog_S3_Grid50-588; Spiekeroog_S3_Grid50-589; Spiekeroog_S3_Grid50-590; Spiekeroog_S3_Grid50-599; Spiekeroog_S3_T1-186; Spiekeroog_S3_T1-188; Spiekeroog_S3_T1-191; Spiekeroog_S3_T1-573; Spiekeroog_S3_T1-7; Spiekeroog_S3_T1-78; Spiekeroog_S3_T2-13; Spiekeroog_S3_T2-143; Spiekeroog_S3_T2-164; Spiekeroog_S3_T2-169; Spiekeroog_S3_T2-599; Spiekeroog_S3_T2-72; Spiekeroog_S3_THR-S1; Spiekeroog_S3_THR-S10; Spiekeroog_S3_THR-S11; Spiekeroog_S3_THR-S12; Spiekeroog_S3_THR-S13; Spiekeroog_S3_THR-S14; Spiekeroog_S3_THR-S15; Spiekeroog_S3_THR-S16; Spiekeroog_S3_THR-S17; Spiekeroog_S3_THR-S18; Spiekeroog_S3_THR-S19; Spiekeroog_S3_THR-S2; Spiekeroog_S3_THR-S20; Spiekeroog_S3_THR-S21; Spiekeroog_S3_THR-S22; Spiekeroog_S3_THR-S23; Spiekeroog_S3_THR-S24; Spiekeroog_S3_THR-S25; Spiekeroog_S3_THR-S26; Spiekeroog_S3_THR-S3; Spiekeroog_S3_THR-S4; Spiekeroog_S3_THR-S5; Spiekeroog_S3_THR-S6; Spiekeroog_S3_THR-S7; Spiekeroog_S3_THR-S8; Spiekeroog_S3_THR-S9; Spiekeroog, German Bight, North Sea; Station label; subterranean estuary; Temperature, water; Transect; UTM Easting, Universal Transverse Mercator; UTM Northing, Universal Transverse Mercator

Type: Dataset

Format: text/tab-separated-values, 4538 data points

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(Table S2) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)

Ahrens, Janis ; Beck, Melanie ; Marchant, Hannah K ; [et al.]

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Publication Date: 2023-02-08

Keywords: ammonium; Ammonium; Calculated; Calculated: DGPS surface elevation - depth below sediment surface; Calculated: NOx - NO2; Calulated: NOx + NH4; Coastal section; Conductivity probe; Conductivity probe with integrated temperature sensor; CSEC; DATE/TIME; DEPTH, sediment/rock; DGPS; estimated for North Beach Seawater; ELEVATION; Event label; Flow through cell; optical measurement (PyroScience); High Energy Beach; iron; Iron; LATITUDE; LONGITUDE; manganese; Manganese; Mass spectrometry; nitrate; Nitrate; Nitrate and Nitrite; nitrite; Nitrite; Nitrogen, inorganic, dissolved; North Sea; Oxygen; Photometric; POINT DISTANCE from start; Salinity; Spiekeroog_S2_T1-174B; Spiekeroog_S2_T1-188; Spiekeroog_S2_T1-191; Spiekeroog_S2_T1-7; Spiekeroog_S2_T1-78; Spiekeroog_S2_T2-13; Spiekeroog_S2_T2-143; Spiekeroog_S2_T2-164; Spiekeroog_S2_T2-169; Spiekeroog_S2_T2-72; Spiekeroog_S2_T3-210; Spiekeroog_S2_T3-229; Spiekeroog_S2_T3-230; Spiekeroog_S2_T3-249-230; Spiekeroog_S2_T3-249-231; Spiekeroog_S2_T3-249-232; Spiekeroog_S2_T3-249-233; Spiekeroog_S2_T3-270; Spiekeroog_S2_T3-291; Spiekeroog_S2_THR-12; Spiekeroog_S2_THR-15; Spiekeroog_S2_THR-18; Spiekeroog_S2_THR-21; Spiekeroog_S2_THR-24; Spiekeroog_S2_THR-27; Spiekeroog_S2_THR-3; Spiekeroog_S2_THR-30; Spiekeroog_S2_THR-33; Spiekeroog_S2_THR-36; Spiekeroog_S2_THR-39; Spiekeroog_S2_THR-42; Spiekeroog_S2_THR-45; Spiekeroog_S2_THR-48; Spiekeroog_S2_THR-51; Spiekeroog_S2_THR-57; Spiekeroog_S2_THR-6; Spiekeroog_S2_THR-9; Spiekeroog, German Bight, North Sea; Station label; subterranean estuary; Temperature, water; Transect; UTM Easting, Universal Transverse Mercator; UTM Northing, Universal Transverse Mercator

Type: Dataset

Format: text/tab-separated-values, 1771 data points

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(Table S1) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)

Ahrens, Janis ; Beck, Melanie ; Marchant, Hannah K ; [et al.]

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Publication Date: 2023-02-08

Keywords: ammonium; Ammonium; Calculated; Calculated: DGPS surface elevation - depth below sediment surface; Calculated: NOx - NO2; Calulated: NOx + NH4; Coastal section; Conductivity probe; Conductivity probe with integrated temperature sensor; CSEC; DATE/TIME; DEPTH, sediment/rock; DGPS; estimated for North Beach Seawater; ELEVATION; Event label; Flow through cell; optical measurement (PyroScience); High Energy Beach; iron; Iron; LATITUDE; LONGITUDE; manganese; Manganese; Mass spectrometry; nitrate; Nitrate; Nitrate and Nitrite; nitrite; Nitrite; Nitrogen, inorganic, dissolved; North Sea; Oxygen; Photometric; POINT DISTANCE from start; Salinity; Spiekeroog_S1_T1-178; Spiekeroog_S1_T1-186; Spiekeroog_S1_T1-188; Spiekeroog_S1_T1-191; Spiekeroog_S1_T1-7; Spiekeroog_S1_T1-78; Spiekeroog_S1_T1E-186; Spiekeroog_S1_T1E-188; Spiekeroog_S1_T1E-191; Spiekeroog_S1_T1E-7; Spiekeroog_S1_T1E-78; Spiekeroog_S1_T1W-186; Spiekeroog_S1_T1W-188; Spiekeroog_S1_T1W-191; Spiekeroog_S1_T1W-7; Spiekeroog_S1_T1W-78; Spiekeroog_S1_T2-13; Spiekeroog_S1_T2-143; Spiekeroog_S1_T2-162; Spiekeroog_S1_T2-164; Spiekeroog_S1_T2-169; Spiekeroog_S1_T2-72; Spiekeroog, German Bight, North Sea; Station label; subterranean estuary; Temperature, water; Transect; UTM Easting, Universal Transverse Mercator; UTM Northing, Universal Transverse Mercator

Type: Dataset

Format: text/tab-separated-values, 1115 data points

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Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)

Ahrens, Janis ; Beck, Melanie ; Marchant, Hannah K ; [et al.]

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In: Supplement to: Ahrens, Janis; Beck, Melanie; Marchant, Hannah K; Ahmerkamp, Soeren; Schnetger, Bernhard; Brumsack, Hans-Jürgen (2020): Seasonality of Organic Matter Degradation regulates Nutrient and Metal Net Fluxes in a High Energy Sandy Beach. Journal of Geophysical Research: Biogeosciences, https://doi.org/10.1029/2019JG005399

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Publication Date: 2024-04-20

Description: During seawater circulation in permeable intertidal sands, organic matter degradation alters the composition of percolating fluids and remineralization products discharge into surficial waters. Concurrently, coastal seawater nutrient and organic matter composition change seasonally due to variations in pelagic productivity. To assess seasonal changes in organic matter degradation in the intertidal zone of a high energy beach (Spiekeroog Island, southern North Sea, Germany), we analyzed shallow pore waters for major redox constituents (oxygen (O2), manganese (Mn), iron (Fe)) and inorganic nitrogen species (nitrite (NO2-), nitrate (NO3-), ammonium (NH4+)) in March, August, and October. Surface water samples from a local time series station were used to monitor seasonal changes in pelagic productivity. O2 and NO3- were the dominating pore water constituents in March and October, whereas dissolved Mn and Fe were more widely distributed in August. Seasonal changes in seawater temperature as well as organic matter and nitrate supply by seawater were assumed to affect microbial rates and respective pathways. Pore water and seawater variability led to seasonally changing constituent effluxes to surface waters. Mn, Fe, and NH4+ effluxes exhibited their minimum in March (3; 2; 7 mmol d-1 per meter shoreline, respectively) and reached their maximum in August (41; 159; 99 mmol d-1 per meter shoreline, respectively). Furthermore, the intertidal sands switched from being a net dissolved inorganic nitrogen (DIN) sink in March (-62 mmol d-1 per meter shoreline) to a net source in August (99 mmol d-1 per meter shoreline). In conclusion, we demonstrated the necessity of seasonal flux evaluations.

Keywords: ammonium; High Energy Beach; iron; manganese; nitrate; nitrite; North Sea; subterranean estuary

Type: Dataset

Format: application/zip, 5 datasets

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Molecular Traits of Dissolved Organic Matter in the Subterranean Estuary of a High-Energy Beach: Indications of Sources and Sinks (2021)

Waska, Hannelore ; Simon, Heike ; Ahmerkamp, Soeren ; [et al.]

In: EPIC3Frontiers in Marine Science, 8, ISSN: 2296-7745

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Publication Date: 2021-04-13

Description: Advective flows of seawater and fresh groundwater through coastal aquifers form a unique ecohydrological interface, the subterranean estuary (STE). Here, freshly produced marine organic matter and oxygen mix with groundwater, which is low in oxygen and contains aged organic carbon (OC) from terrestrial sources. Along the groundwater flow paths, dissolved organic matter (DOM) is degraded and inorganic electron acceptors are successively used up. Because of the different DOM sources and ages, exact degradation pathways are often difficult to disentangle, especially in high-energy environments with dynamic changes in beach morphology, source composition, and hydraulic gradients. From a case study site on a barrier island in the German North Sea, we present detailed biogeochemical data from freshwater lens groundwater, seawater, and beach porewater samples collected over different seasons. The samples were analyzed for physico-chemistry (e.g., salinity, temperature, dissolved silicate), (reduced) electron acceptors (e.g., oxygen, nitrate, and iron), and dissolved organic carbon (DOC). DOM was isolated and molecularly characterized via soft-ionization ultra-high-resolution mass spectrometry, and molecular formulae were identified in each sample. We found that the islands’ freshwater lens harbors a surprisingly high DOM molecular diversity and heterogeneity, possibly due to patchy distributions of buried peat lenses. Furthermore, a comparison of DOM composition of the endmembers indicated that the Spiekeroog high-energy beach STE conveys chemically modified, terrestrial DOM from the inland freshwater lens to the coastal ocean. In the beach intertidal zone, porewater DOC concentrations, lability of DOM and oxygen concentrations, decreased while dissolved (reduced) iron and dissolved silicate concentrations increased. This observation is consistent with the assumption of a continuous degradation of labile DOM along a cross-shore gradient, even in this dynamic environment. Accordingly, molecular properties of DOM indicated enhanced degradation, and “humic-like” fluorescent DOM fraction increased along the flow paths, likely through accumulation of compounds less susceptible to microbial consumption. Our data indicate that the high-energy beach STE is likely a net sink of OC from the terrestrial and marine realm, and that barrier islands such as Spiekeroog may act as efficient “digestors” of organic matter.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

Format: application/pdf

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Seasonality of Organic Matter Degradation Regulates Nutrient and Metal Net Fluxes in a High Energy Sandy Beach (2021)

Ahrens, Janis ; Beck, Melanie ; Marchant, Hannah K. ; [et al.]

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Publication Date: 2021-10-12

Description: During seawater circulation in permeable intertidal sands, organic matter degradation alters the composition of percolating fluids and remineralization products discharge into surficial waters. Concurrently, coastal seawater nutrient and organic matter composition change seasonally due to variations in pelagic productivity. To assess seasonal changes in organic matter degradation in the intertidal zone of a high energy beach (Spiekeroog Island, southern North Sea, Germany), we analyzed shallow pore waters for major redox constituents (oxygen [O2], manganese [Mn], and iron [Fe]) and inorganic nitrogen species (nitrite [NO2−], nitrate [NO3−], and ammonium [NH4+]) in March, August, and October. Surface water samples from a local time series station were used to monitor seasonal changes in pelagic productivity. O2 and NO3− were the dominating pore water constituents in March and October. Dissolved Mn, Fe, and NH4+ were more widely distributed in August. Seasonal changes in seawater temperature as well as organic matter and nitrate supply by seawater were assumed to affect microbial rates and degradation pathways. Pore water and seawater variability led to seasonally changing constituent effluxes to surface waters. Mn, Fe, and NH4+ effluxes are minimal in March and reached their maximum in August. Furthermore, the intertidal sands switched from a net dissolved inorganic nitrogen sink in March to a net source in August. In conclusion, seasonal effects on intertidal pore water biogeochemistry affect constituent fluxes across the sediment-water interface. The seasonality of the beach bioreactor must be considered when fluxes are extrapolated to annual timescales.

Keywords: 551.9 ; submarine groundwater discharge ; subterranean estuary ; oxygen ; nitrogen ; manganese ; iron

Language: English

Type: map

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DSi as a tracer for submarine groundwater discharge (2019)

Oehler, Till ; Tamborski, Joseph ; Rahman, Shaily ; [et al.]

Frontiers Media

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Publication Date: 2022-10-26

Description: © The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Oehler, T., Tamborski, J., Rahman, S., Moosdorf, N., Ahrens, J., Mori, C., Neuholz, R., Schnetger, B., & Beck, M. DSi as a tracer for submarine groundwater discharge. Frontiers in Marine Science, 6, (2019): 563, doi:10.3389/fmars.2019.00563.

Description: Submarine groundwater discharge (SGD) is an important source of nutrients and metals to the coastal ocean, affects coastal ecosystems, and is gaining recognition as a relevant water resource. SGD is usually quantified using geochemical tracers such as radon or radium. However, a few studies have also used dissolved silicon (DSi) as a tracer for SGD, as DSi is usually enriched in groundwater when compared to surface waters. In this study, we discuss the potential of DSi as a tracer in SGD studies based on a literature review and two case studies from contrasting environments. In the first case study, DSi is used to calculate SGD fluxes in a tropical volcanic-carbonate karstic region (southern Java, Indonesia), where SGD is dominated by terrestrial groundwater discharge. The second case study discusses DSi as a tracer for marine SGD (i.e., recirculated seawater) in the tidal flat area of Spiekeroog (southern North Sea), where SGD is dominantly driven by tidal pumping through beach sands. Our results indicate that DSi is a useful tracer for SGD in various lithologies (e.g., karstic, volcanic, complex) to quantify terrestrial and marine SGD fluxes. DSi can also be used to trace groundwater transport processes in the sediment and the coastal aquifer. Care has to be taken that all sources and sinks of DSi are known and can be quantified or neglected. One major limitation is that DSi is used by siliceous phytoplankton and therefore limits its applicability to times of the year when primary production of siliceous phytoplankton is low. In general, DSi is a powerful tracer for SGD in many environments. We recommend that DSi should be used to complement other conventionally used tracers, such as radon or radium, to help account for their own shortcomings.

Description: TO, NM, and the presented case study 1 were funded through the BMBF junior research group SGD-NUT (grant #01LN1307A). Open access publication fees are paid by Leibniz-Centre for Tropical Marine Research internal funds. The presented case study 2 was financially supported by the DFG Research Group “BioGeoChemsitry of Tidal Flats”, the Ph.D. Research Training Group “The ecology of molecules” funded by the Ministry for Science and Culture of Lower Saxony, and the Institute for Chemistry and Biology of the Marine Environment, University of Oldenburg.

Keywords: Submarine groundwater discharge ; DSi ; Silica ; Tracer ; Radon ; Radium

Repository Name: Woods Hole Open Access Server

Type: Article

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