Aninda Mazumdar scite author profile

Biogeochemistry of oxygen minimum zone (OMZ) sediments, which are characterized by high input of labile organic matter, have crucial bearings on the benthic biota, gas and metal fluxes across the sediment-water interface, and carbon-sulfur cycling. Here we couple pore-fluid chemistry and comprehensive microbial diversity data to reveal the sedimentary carbon-sulfur cycle across a water-depth transect covering the entire thickness of eastern Arabian Sea OMZ, off the west coast of India. Geochemical data show remarkable increase in average total organic carbon content and aerial sulfate reduction rate (JSO42−) in the sediments of the OMZ center coupled with shallowing of sulfate methane transition zone and hydrogen sulfide and ammonium build–up. Total bacterial diversity, including those of complex organic matter degraders, fermentative and exoelectrogenic bacteria, and sulfate-reducers (that utilize only simple carbon compounds) were also found to be highest in the same region. The above findings indicate that higher organic carbon sequestration from the water-columns (apparently due to lower benthic consumption, biodegradation and biotransformation) and greater bioavailability of simple organic carbon compounds (apparently produced by fermetative microflora of the sediments) are instrumental in intensifying the carbon-sulfur cycle in the sediments of the OMZ center.

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Dissolved inorganic carbon (DIC) and its δ13C in the Ganga (Hooghly) River estuary, India: Evidence of DIC generation via organic carbon degradation and carbonate dissolution

Samanta

Dalai

Pattanaik

et al. 2015

Geochimica et Cosmochimica Acta

103

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Tracing the Paleo sulfate‐methane transition zones and H₂S seepage events in marine sediments: An application of C‐S‐Mo systematics

Peketi

Mazumdar

Joshi

et al. 2012

Geochem Geophys Geosyst

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[1] Microbially mediated anaebic oxidation of methane (AOM) coupled with sulfate consumption within the sulfate methane transition zone (SMTZ) in marine sediments is a widely recorded biogeochemical reaction and has profound influence on the atmospheric CH 4 budget, marine carbon cycle and composition of sediment pore fluids. Recognizing the paleo-SMTZs in the marine sediments/rock records can throw light on the variation of paleo-methane fluxes and occurrences of cold seep (H 2 S + CH 4 ) events through geologic time. Here, we present results from carbonate carbon, pyrite sulfur and molybdenum analyses for two sediment cores overlying the methane hydrate deposits in the Bay of Bengal. The results show intimate association of isotopically depleted carbonate carbon and enriched pyrite sulfur, constraining the paleo SMTZ within the sediment column. In addition, anomalous enrichments of Mo concentrations indicate hydrogen sulfide seepage events. Here, we propose a geochemical tool using C-S-Mo sytematics to decipher the paleo-SMTZs in marine sediments and rocks.

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Evidence of paleo–cold seep activity from the Bay of Bengal, offshore India

Mazumdar

Dewangan

Joäo

et al. 2009

Geochem Geophys Geosyst

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We report evidence of paleo–cold seep associated activities, preserved in methane‐derived carbonates in association with chemosynthetic clams (Calyptogena sp.) from a sediment core in the Krishna‐Godavari basin, Bay of Bengal. Visual observations and calculations based on high‐resolution wet bulk density profile of a core collected on board R/V Marion Dufresne (May 2007) show zones of sharp increase in carbonate content (10–55 vol %) within 16–20 meters below seafloor (mbsf). The presence of Calyptogena clam shells, chimneys, shell breccias with high Mg calcite cement, and pyrite within this zone suggest seepage of methane and sulfide‐bearing fluid to the seafloor in the past. Highly depleted carbon isotopic values (δ13C ranges from −41 to −52‰ VPDB) from these carbonates indicate carbon derived via anaerobic oxidation of methane. Extrapolated mean calendar age (∼58.7 ka B.P.) of the clastic sediments at a depth of 16 mbsf is close to the upper limit of the U‐Th based depositional age (46.2 ± 3.7 and 53.0 ± 1.6 ka) of authigenic carbonates sampled from this level, thereby constraining the younger age limit of the carbonate deposition/methane expulsion events. The observed carbonate deposition might have resulted from the flow of methane‐enriched fluids through the fracture network formed because of shale diapirism.

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Seabed morphology and gas venting features in the continental slope region of Krishna–Godavari basin, Bay of Bengal: Implications in gas-hydrate exploration

Dewangan

Ramprasad

Ramana

et al. 2010

Marine and Petroleum Geology

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Aninda Mazumdar

Enhanced carbon-sulfur cycling in the sediments of Arabian Sea oxygen minimum zone center

Dissolved inorganic carbon (DIC) and its δ13C in the Ganga (Hooghly) River estuary, India: Evidence of DIC generation via organic carbon degradation and carbonate dissolution

Tracing the Paleo sulfate‐methane transition zones and H₂S seepage events in marine sediments: An application of C‐S‐Mo systematics

Evidence of paleo–cold seep activity from the Bay of Bengal, offshore India

Seabed morphology and gas venting features in the continental slope region of Krishna–Godavari basin, Bay of Bengal: Implications in gas-hydrate exploration

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Aninda Mazumdar

Enhanced carbon-sulfur cycling in the sediments of Arabian Sea oxygen minimum zone center

Dissolved inorganic carbon (DIC) and its δ13C in the Ganga (Hooghly) River estuary, India: Evidence of DIC generation via organic carbon degradation and carbonate dissolution

Tracing the Paleo sulfate‐methane transition zones and H2S seepage events in marine sediments: An application of C‐S‐Mo systematics

Evidence of paleo–cold seep activity from the Bay of Bengal, offshore India

Seabed morphology and gas venting features in the continental slope region of Krishna–Godavari basin, Bay of Bengal: Implications in gas-hydrate exploration

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Tracing the Paleo sulfate‐methane transition zones and H₂S seepage events in marine sediments: An application of C‐S‐Mo systematics