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  • 1
    Online Resource
    Online Resource
    Modellierung und Bilanzierung benthischer Stoffflüsse und Stoffumsätze in marinen Oberflächensedimenten : ein Modellansatz zur Beschreibung diagenetischer Prozesse an zwei Fallbeispielen (2001)
    Kiel
    Details Availability
    Keywords: Meeressediment ; Oberflächensediment ; Kreislauf ; Geochemie ; Frühdiagenese ; Dissertation ; Nordsee ; Arabisches Meer ; Hochschulschrift
    Type of Medium: Online Resource
    Pages: 1 Online-Ressource ( 165Seiten = 15MB) , Ill., graph. Darst., Kt.
    URL: https://oceanrep.geomar.de/id/eprint/31070/
    Language: German
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  • 2
    Online Resource
    Online Resource
    Modellierung und Bilanzierung benthischer Stoffflüsse und Stoffumsätze in marinen Oberflächensedimenten : ein Modellansatz zur Beschreibung diagenetischer Prozesse an zwei Fallbeispielen (2001)
    Details Availability
    Keywords: Meeressediment ; Oberflächensediment ; Kreislauf ; Geochemie ; Frühdiagenese ; Dissertation ; Nordsee ; Arabisches Meer ; Hochschulschrift
    Type of Medium: Online Resource
    Pages: Online-Ressource (165 S = 14.77 MB, Text) , Ill., graph. Darst., Kt.
    Edition: [Electronic ed.]
    URL: http://eldiss.uni-kiel.de/macau/receive/dissertation_diss_486
    URL: http://nbn-resolving.de/urn:nbn:de:gbv:8-diss-4860
    URN: urn:nbn:de:gbv:8-diss-4860
    Language: German
    Note: Kiel, Univ., Diss., 2001
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  • 3
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    Numerical modeling of carbonate crust formation at cold vent sites: significance for fluid and methane budgets and chemosynthetic biological communities (2004)
    Elsevier
    In:  Earth and Planetary Science Letters, 221 . pp. 337-353.
    Details
    Publication Date: 2019-09-23
    Description: At many cold vent sites authigenic carbonates precipitate due to the release of carbonate alkalinity during the anaerobic oxidation of methane. Carbonate precipitation often induces the formation of massive crusts at the sediment surface or within surface sediments. The range of physical and biogeochemical conditions allowing for the formation of carbonate crusts is largely unknown so that the significance of these widespread manifestations of fluid flow is unclear. Here, we use numerical modeling to investigate the conditions that induce carbonate crust formation in the sediment and the effect of crust formation on sediment porosity and fluid flow rate. Starting with the conditions prevailing at a previously investigated reference site located on Hydrate Ridge, off Oregon, several parameters are systematically varied in a number of numerical experiments. These parameters include coefficients of bioturbation and bioirrigation, sedimentation rate, fluid flow velocity, methane concentration in the ascending vent fluids, and pH and saturation state at the sediment–water interface. The simulations show that carbonate crusts in the sediments only form if the fluids contain sufficient dissolved methane (〉50 mM) and if bioturbation coefficients are low (〈0.05 cm2 a−1). Moreover, high sedimentation rates (〉50 cm ka−1) inhibit crust formation. Bioirrigation induces a downward displacement of the precipitation zone and accelerates the formation of a solid crust. Crusts only form over a rather narrow range of upward fluid flow velocities (20–60 cm a−1), which is somewhat enlarged (up to 90 cm a−1) if the overlying bottom waters are supersaturated with respect to calcite. At higher flow rates, methane is rapidly exported into the water column so that methane oxidation and carbonate precipitation cannot proceed within the surface sediment. The formation of a several centimeters thick carbonate crust in surface sediments is typically completed after a few hundred years (100–500 a). Crust formation reduces the supply of methane to surface sediments which imposes a strong resistance against diffusive and advective methane transport. Therefore, rates of anaerobic methane oxidation and sulfide production are diminished and thus the density and metabolism of chemosynthetic biological communities is limited by crust formation. Due to the moderate flow rates and the slow diffusive transport, only very little methane escapes into the bottom water overlying carbonate-encrusted vent areas.
    Type: Article , PeerReviewed
    Format: text
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 4
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    Seasonal dynamics of the North Sea sediments using a three-dimensional coupled sediment–water model system (2004)
    Elsevier
    In:  Continental Shelf Research, 24 (10). pp. 1099-1127.
    Details
    Publication Date: 2016-09-21
    Description: A high-resolution early diagenetic model for the North Sea sediments has been coupled with a pelagic ecosystem model to quantify the three-dimensional processes in the coupled sediment–water system from the sea surface to a sediment depth of 11 cm focussing on the processes in the sediments of the North Sea. The pelagic ecosystem model ECOHAM1 simulates the 1986 phytoplankton dynamics considering circulation, temperature, nutrient availability in the water column and the resulting flux of particulate organic carbon (POC) onto the sediment. These seasonal and regional variable water column processes are considered as forcing for the early diagenetic model C. CANDI, which calculates the processes in the upper sediment column, represented by 14 dissolved and 6 solid species, resolved with 84 vertical levels. With the coupled model the daily benthic fluxes of POC, oxygen, nitrate, phosphate, and sulphate at the sediment–water interface for each of the 1158 horizontal cells covering the whole North Sea area has been determined. The simulations show the seasonal and regional variations in the pelagic and the sediment system. The coupled model reproduces very well measured oxygen and nitrate penetration depths at selected validation stations. A vertical section from Fair Isle into the German Bight in summer demonstrates high spatial phosphate variability in the water column and in the sediment. Observations on the sediment–water interface fluxes and of concentration distributions in the sediment are very sparse. The results of this high-resolution model allows the calculation of budgets at the sediment–water interface for the whole simulation area. The annual cumulated phosphate flux across the sediment–water interface exhibits strong fluxes concentrated in a narrow band off the continental coast in shallow waters over 40 mmol m−2 yr−1, whereas in the central North Sea fluxes are lower than 30 mmol m−2 yr−1. Simulated annual cycle of fluxes at the sediment–water interface at a position located in the central North Sea showed a phosphate flux shifted by 1 month compared to the organic matter flux, whereas the sulphate flux into the sediment showed an overall time lag of about 5 months.
    Type: Article , PeerReviewed
    Format: text
    DOI: 10.1016/j.csr.2004.03.010
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 5
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    Modellierung und Bilanzierung bentischer Stoffflüsse und Stoffumsätze in marinen Oberflächensedimenten: Ein Modellansatz zur Beschreibung diagenetischer Prozesse an zwei Fallbeispielen (2001)
    Details
    Publication Date: 2023-02-02
    Description: Ziel dieser Arbeit ist es, die Zusammenhänge der Prozesse im Sediment besser zu verstehen und die Rückführung von Stoffen aus dem Sediment in die Wassersäule genauer abzuschätzen. Als Basis wurde das von Boudreau (199 6b) entwickelte numerische Modell zur Frühdiagenese im Sediment CANDI (Carbon And Nutrient DIagenesis) verwendet. Die Arbeit gliedert sich in zwei Teile. Der erste Teil beschreibt die Prozesse an einzelnen gut untersuchten Stationen in Sedimenten der Tiefsee des Arabischen Meeres. Im zweiten Teil werden Konzentrationsverteilungen im Sediment und Flüsse zwischen Sediment und Bodenwasser in der Nordsee beckenweit simuliert. Das Arabische Meer ist aufgrund der durch die zyklischen Änderungen der Monsunwinde hervorgerufenen Saisonalität, sehr gut geeignet, nicht nur die Austauschprozesse zu quantifizieren, sondern darüber hinaus zu untersuchen, ob sich die saisonalen Schwankungen an der Meeresoberfläche auch in den frühdiagenetischen Prozessen im Oberflächensediment widerspiegeln. Auch in der Nordsee ist eine starke Saisonalität vorhanden, deren Einfluss auf die Prozesse im Sediment mit dem Modell beschrieben und untersucht werden kann.
    Type: Thesis , NonPeerReviewed
    Format: text
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    OceanRep: Thesis - not published by a publisher
  • 6
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    Fluid flow, methane fluxes, carbonate precipitation and biogeochemical turnover in gas hydrate-bearing sedimenta at Hydrate Ridge, Cascadia Margin: Numerical modeling and mass balances (2003)
    Elsevier
    In:  Geochimica et Cosmochimica Acta, 67 (18). pp. 3403-3421.
    Details
    Publication Date: 2017-09-08
    Description: A numerical model was applied to investigate and to quantify biogeochemical processes and methane turnover in gas hydrate-bearing surface sediments from a cold vent site situated at Hydrate Ridge, an accretionary structure located in the Cascadia Margin subduction zone. Steady state simulations were carried out to obtain a comprehensive overview on the activity in these sediments which are covered with bacterial mats and are affected by strong fluid flow from below. The model results underline the dominance of advective fluid flow that forces a large inflow of methane from below (869 mumol cm(-2) a(-1)) inducing high oxidation rates in the surface layers. Anaerobic methane oxidation is the major process, proceeding at a depth-integrated rate of 870 mumol cm(-2) a(-1). A significant fraction (14%) of bicarbonate produced by anaerobic methane oxidation is removed from the fluids by precipitation of authigenic aragonite and calcite. The total rate of carbonate precipitation (120 mumol cm(-2) a(-1)) allows for the build-up of a massive carbonate layer with a thickness of I m over a period of 20,000 years. Aragonite is the major carbonate mineral formed by anaerobic methane oxidation if the flow velocity of methane-charge fluids is high enough ( greater than or equal to10 cm a(-1)) to maintain super-saturation with respect to this highly soluble carbonate phase. It precipitates much faster within the studied surface sediments than previously observed in abiotic laboratory experiments, suggesting microbial catalysis. The investigated station is characterized by high carbon and oxygen turnover rates (approximate to1000 mumol cm(-2) a(-1)) that are well beyond the rates observed at other continental slope sites not affected by fluid venting. This underlines the strong impact of fluid venting on the benthic system, even though the flow velocity of 10 cm a(-1) derived by the model is relative low compared to fluid flow rates found at other cold vent sites. Non-steady state simulations using measured fluid flow velocities as forcing demonstrate a rapid respond of the sediments within a few days to changes in advective flow. Moreover, they reveal that efficient methane oxidation in these sediments prevents methane outflow into the bottom water over a wide range of fluid flow velocities (〈80 cm a(-1)). Only at flow rates exceeding approximately 100 cm a(-1), does dissolved methane break through the sediment surface to induce large fluxes of up to 5000 mumol CH4 cm(2) a(-1) into the overlying bottom water.
    Type: Article , PeerReviewed
    Format: text
    DOI: 10.1016/S0016-7037(03)00127-3
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 7
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    Simulation of long-term feedbacks from authigenic carbonate crust formation at cold vent sites (2005)
    Elsevier
    In:  Chemical Geology, 216 (1-2). pp. 157-174.
    Details
    Publication Date: 2017-12-07
    Description: Fluid flow at cold vent sites is usually driven by the ascent of overpressured fluids from subsurface reservoirs. Porosity changes in surface sediments due to precipitation and dissolution of authigenic carbonates affects fluid flow and biogeochemical turnover. From observations, it is known that carbonate precipitates often occur in distinct layers in high concentrations, surrounded by layers with low carbonate content. Using a non-steady state model, we simulate aragonite and calcite precipitation and dissolution in a 2-m long sediment column, located under a bacterial mat at Hydrate Ridge, Cascadia accretionary margin. Assuming a constant pressure gradient over 7000 years, fluid flow, anaerobic oxidation of methane (AOM) rates, and carbonate precipitation and dissolution rates show strong oscillations evoked by changes in permeability and fluid flow over time. The porosity reaches values below 0.35 in the carbonate layers that reduce the fluid flow velocity from an initial value of 30 cm a−1 to a minimum value of about 2 cm a−1. These significant changes in the fluid flow system displace the depth of sulfate penetration. The simulation predicts cycles of carbonate crust formation and dissolution with a duration of 2000–2700 years resulting in several distinct carbonate layers. During periods of high fluid flow, AOM reaches rates over 1000 μmol cm−1 a−1 and methane fluxes out of the sediment reach 200 μmol cm−1 a−1. During periods of low fluid flow, AOM is about 450 μmol cm−1 a−1 and the methane flux into the bottom water vanishes completely. The oscillations are dampened so that fluid flow and biogeochemical turnover slowly approach steady state after about 7000 years towards the end of the simulation period, showing a 1-m-thick area at the surface with carbonate concentrations of about 25 wt.%. Flow oscillations may also impact the colonization of chemoautotrophic larva and bacteria in and on the sediment. The frequency of precipitation–dissolution cycles of 2000–2700 years is long enough for vent biota to react to changes in the sediments, for example explaining the occurrence of buried Calyptogena and Acharax mussel shells at former vent sites that are not presently active. The evaluation of side scan sonar data reveals large areas of cemented sediments and carbonate pavements north of the investigated site. The situation found in the investigated core may be characterized as intermediate stage of carbonate cementation. This ongoing process will also form a solid carbonate pavement at this site in the future.
    Type: Article , PeerReviewed
    Format: text
    DOI: 10.1016/j.chemgeo.2004.11.002
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    OceanRep: Article in a Scientific Journal - peer-reviewed
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