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Understanding the Anodic Mechanism of a Seafloor Fuel Cell: Interactions between Geochemistry and Microbial Activity
Seafloor fuel cells made with graphite electrodes generate electricity by promoting electron transfer in response to a natural voltage difference (-0.7 to -0.8 V) between anoxic sediments and overlying oxic seawater. Geochemical impacts of a seafloor fuel cell on sediment solids and porewaters were...
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| Published in: | Biogeochemistry 2005-10, Vol.76 (1), p.113-139 |
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| cites | cdi_FETCH-LOGICAL-c421t-7b924244c624fadd28b927b2cfb078650edb5ce64e9e9b08fea478b298bc75ea3 |
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| container_title | Biogeochemistry |
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| creator | Ryckelynck, Natacha Stecher, Hilmar A. Reimers, Clare E. |
| description | Seafloor fuel cells made with graphite electrodes generate electricity by promoting electron transfer in response to a natural voltage difference (-0.7 to -0.8 V) between anoxic sediments and overlying oxic seawater. Geochemical impacts of a seafloor fuel cell on sediment solids and porewaters were examined to identify the anodic mechanisms and substrates available for current production. In an estuarine environment with little dissolved sulfide, solid-phase acid volatile sulfide and$\text{Cr}^{2+}$-reducible sulfur minerals decreased significantly toward the anode after 7 months of nearly continuous energy harvesting. Porewater iron and sulfate increased by millimolar amounts. Scanning electron microscope images showed a biofilm overcoating the anode, and electron microprobe analyses revealed accumulations of sulfur, iron, silicon and phosphorus at the electrode surface. Sulfur deposition was also observed on a laboratory fuel cell anode used to generate electricity with only dissolved sulfide as an electron donor. Moreover, current densities and voltages displayed by these purely chemical cells were similar to the values measured with field devices. These results indicate that electron transfer to seafloor fuel cells can readily result in the oxidation of dissolved and solid-phase forms of reduced sulfur producing mainly$\text{S}^{0}$which deposits at the electrode surface. This oxidation product is consistent with the observed enrichment of bacteria most closely related to Desulfobulbus/Desulfocapsa genera within the anode biofilm, and its presence is proposed to promote a localized biogeochemical cycle whereby biofilm bacteria regenerate sulfate and sulfide. This electron-shuttling mechanism may co-occur while these or other bacteria use the anode directly as a terminal electron acceptor. |
| doi_str_mv | 10.1007/s10533-005-2671-3 |
| format | article |
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These results indicate that electron transfer to seafloor fuel cells can readily result in the oxidation of dissolved and solid-phase forms of reduced sulfur producing mainly$\text{S}^{0}$which deposits at the electrode surface. This oxidation product is consistent with the observed enrichment of bacteria most closely related to Desulfobulbus/Desulfocapsa genera within the anode biofilm, and its presence is proposed to promote a localized biogeochemical cycle whereby biofilm bacteria regenerate sulfate and sulfide. 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These results indicate that electron transfer to seafloor fuel cells can readily result in the oxidation of dissolved and solid-phase forms of reduced sulfur producing mainly$\text{S}^{0}$which deposits at the electrode surface. This oxidation product is consistent with the observed enrichment of bacteria most closely related to Desulfobulbus/Desulfocapsa genera within the anode biofilm, and its presence is proposed to promote a localized biogeochemical cycle whereby biofilm bacteria regenerate sulfate and sulfide. 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Geochemical impacts of a seafloor fuel cell on sediment solids and porewaters were examined to identify the anodic mechanisms and substrates available for current production. In an estuarine environment with little dissolved sulfide, solid-phase acid volatile sulfide and$\text{Cr}^{2+}$-reducible sulfur minerals decreased significantly toward the anode after 7 months of nearly continuous energy harvesting. Porewater iron and sulfate increased by millimolar amounts. Scanning electron microscope images showed a biofilm overcoating the anode, and electron microprobe analyses revealed accumulations of sulfur, iron, silicon and phosphorus at the electrode surface. Sulfur deposition was also observed on a laboratory fuel cell anode used to generate electricity with only dissolved sulfide as an electron donor. Moreover, current densities and voltages displayed by these purely chemical cells were similar to the values measured with field devices. These results indicate that electron transfer to seafloor fuel cells can readily result in the oxidation of dissolved and solid-phase forms of reduced sulfur producing mainly$\text{S}^{0}$which deposits at the electrode surface. This oxidation product is consistent with the observed enrichment of bacteria most closely related to Desulfobulbus/Desulfocapsa genera within the anode biofilm, and its presence is proposed to promote a localized biogeochemical cycle whereby biofilm bacteria regenerate sulfate and sulfide. This electron-shuttling mechanism may co-occur while these or other bacteria use the anode directly as a terminal electron acceptor.</abstract><cop>Heidelberg</cop><pub>Springer</pub><doi>10.1007/s10533-005-2671-3</doi><tpages>27</tpages></addata></record> |
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| identifier | ISSN: 0168-2563 |
| ispartof | Biogeochemistry, 2005-10, Vol.76 (1), p.113-139 |
| issn | 0168-2563 1573-515X |
| language | eng |
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| source | JSTOR Archival Journals and Primary Sources Collection; Springer Nature |
| subjects | Animal and plant ecology Animal, plant and microbial ecology Anodes Bacteria Biofilms Biogeochemical cycles Biological and medical sciences Chemical analysis Desulfobulbus Earth sciences Earth, ocean, space Electric current Electricity Electrodes Electrons Estuarine environments Exact sciences and technology Fuel cells Fuel technology Fundamental and applied biological sciences. Psychology Geochemistry Graphite Marine and continental quaternary Microbial activity Ocean floor Oxidation Pore water Sea water ecosystems Seawater Sediments Sulfates Sulfides Sulfur Surficial geology Synecology Water analysis |
| title | Understanding the Anodic Mechanism of a Seafloor Fuel Cell: Interactions between Geochemistry and Microbial Activity |
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