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  • 1
    facet.materialart.
    Unknown
    Microstructure and composition of marine aggregates as co-determinants for vertical particulate organic carbon transfer in the global ocean (2020)
    Copernicus Publications (EGU)
    Details
    Publication Date: 2023-02-08
    Description: Marine aggregates are the vector for biogenically bound carbon and nutrients from the euphotic zone to the interior of the oceans. To improve the representation of this biological carbon pump in the global biogeochemical HAMburg Ocean Carbon Cycle (HAMOCC) model, we implemented a novel Microstructure, Multiscale, Mechanistic, Marine Aggregates in the Global Ocean (M4AGO) sinking scheme. M4AGO explicitly represents the size, microstructure, heterogeneous composition, density and porosity of aggregates and ties ballasting mineral and particulate organic carbon (POC) fluxes together. Additionally, we incorporated temperature-dependent remineralization of POC. We compare M4AGO with the standard HAMOCC version, where POC fluxes follow a Martin curve approach with (i) linearly increasing sinking velocity with depth and (ii) temperature-independent remineralization. Minerals descend separately with a constant speed. In contrast to the standard HAMOCC, M4AGO reproduces the latitudinal pattern of POC transfer efficiency, as recently constrained by Weber et al. (2016). High latitudes show transfer efficiencies of ≈0.25±0.04, and the subtropical gyres show lower values of about 0.10±0.03. In addition to temperature as a driving factor for remineralization, diatom frustule size co-determines POC fluxes in silicifier-dominated ocean regions, while calcium carbonate enhances the aggregate excess density and thus sinking velocity in subtropical gyres. Prescribing rising carbon dioxide (CO2) concentrations in stand-alone runs (without climate feedback), M4AGO alters the regional ocean atmosphere CO2 fluxes compared to the standard model. M4AGO exhibits higher CO2 uptake in the Southern Ocean compared to the standard run, while in subtropical gyres, less CO2 is taken up. Overall, the global oceanic CO2 uptake remains the same. With the explicit representation of measurable aggregate properties, M4AGO can serve as a test bed for evaluating the impact of aggregate-associated processes on global biogeochemical cycles and, in particular, on the biological carbon pump.
    Type: Article , PeerReviewed
    Format: text
    Location Call Number Limitation Availability
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 2
    facet.materialart.
    Unknown
    Small sinking particles control anammox rates in the Peruvian oxygen minimum zone (2021)
    Nature Research
    Details
    Publication Date: 2024-02-07
    Description: Anaerobic oxidation of ammonium (anammox) in oxygen minimum zones (OMZs) is a major pathway of oceanic nitrogen loss. Ammonium released from sinking particles has been suggested to fuel this process. During cruises to the Peruvian OMZ in April–June 2017 we found that anammox rates are strongly correlated with the volume of small particles (128–512 µm), even though anammox bacteria were not directly associated with particles. This suggests that the relationship between anammox rates and particles is related to the ammonium released from particles by remineralization. To investigate this, ammonium release from particles was modelled and theoretical encounters of free-living anammox bacteria with ammonium in the particle boundary layer were calculated. These results indicated that small sinking particles could be responsible for ~75% of ammonium release in anoxic waters and that free-living anammox bacteria frequently encounter ammonium in the vicinity of smaller particles. This indicates a so far underestimated role of abundant, slow-sinking small particles in controlling oceanic nutrient budgets, and furthermore implies that observations of the volume of small particles could be used to estimate N-loss across large areas.
    Type: Article , PeerReviewed
    Format: text
    Location Call Number Limitation Availability
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 3
    facet.materialart.
    Unknown
    Sediment acidification and temperature increase in an artificial CO2 vent (2021)
    Elsvier
    Details
    Publication Date: 2024-02-07
    Description: Highlights • A mechanistic explanation is provided for the observed CO2 loss in the sediments. • Reactions of CO2 with the sediment lead to significant heating. • The observations were modeled including reactions and losses due to lateral transport. • CO2 leakage will lead to very local effects. Abstract We investigated the effect of an artificial CO2 vent (0.0015−0.037 mol s−1), simulating a leak from a reservoir for carbon capture and storage (CCS), on the sediment geochemistry. CO2 was injected 3 m deep into the seafloor at 120 m depth. With increasing mass flow an increasing number of vents were observed, distributed over an area of approximately 3 m. In situ profiling with microsensors for pH, T, O2 and ORP showed the geochemical effects are localized in a small area around the vents and highly variable. In measurements remote from the vent, the pH reached a value of 7.6 at a depth of 0.06 m. In a CO2 venting channel, pH reduced to below 5. Steep temperature profiles were indicative of a heat source inside the sediment. Elevated total alkalinity and Ca2+ levels showed calcite dissolution. Venting decreased sulfate reduction rates, but not aerobic respiration. A transport-reaction model confirmed that a large fraction of the injected CO2 is transported laterally into the sediment and that the reactions between CO2 and sediment generate enough heat to elevate the temperature significantly. A CO2 leak will have only local consequences for sediment biogeochemistry, and only a small fraction of the escaped CO2 will reach the sediment surface.
    Type: Article , PeerReviewed , info:eu-repo/semantics/article
    Format: text
    Format: text
    Location Call Number Limitation Availability
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 4
    facet.materialart.
    Unknown
    (Table S4) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)
    PANGAEA
    Details
    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
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 5
    facet.materialart.
    Unknown
    (Table S5) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)
    PANGAEA
    Details
    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
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 6
    facet.materialart.
    Unknown
    (Table S3) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)
    PANGAEA
    Details
    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
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 7
    facet.materialart.
    Unknown
    (Table S2) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)
    PANGAEA
    Details
    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
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 8
    facet.materialart.
    Unknown
    (Table S1) Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)
    PANGAEA
    Details
    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
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 9
    facet.materialart.
    Unknown
    Seasonal oxygen, nutrient, Mn, and Fe data for intertidal pore waters and adjacent seawater of Spiekeroog Island North Beach (Germany) (2019)
    PANGAEA
    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
    Details
    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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    DATA PANGAEA
  • 10
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    N2 fixation in free‐floating filaments of Trichodesmium is higher than in transiently suboxic colony microenvironments (2018)
    WILEY-BLACKWELL PUBLISHING
    In:  EPIC3New Phytologist, WILEY-BLACKWELL PUBLISHING, ISSN: 0028-646X
    Details
    Publication Date: 2019-01-23
    Repository Name: EPIC Alfred Wegener Institut
    Type: Article , isiRev
    Format: application/pdf
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    PAPER (OA)
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