Late Holocene foraminifera of Blake Ridge diapir: Assemblage variation and stable-isotope record in gas-hydrate bearing sediments

The presence of gas hydrates on the Blake Ridge diapir, northeastern Atlantic Ocean, offers an opportunity to study the impact of methane seepage on the ecology and geochemistry of benthic foraminifera in the late Holocene. Three push cores, covering a time span of similar to 1000 yrs, were retrieved from three distinct microhabitats at the top of the diapir at a water depth of similar to 2150 m: (i) sediments away from seepage (control core), (ii) sediments overlain by clusters of methanotrophic and thiotrophic bivalves, and (iii) chemoautotrophic microbial mats. The foraminiferal assemblages at the two seep sites are marked by a reduction in benthic foraminiferal species diversity, coupled with a near-absence of agglutinated species. However, an opportunistic population rise in CH4- or H2S-tolerant calcareous species (e.g., Globocassidulina subglobosa and Cassidulina laevigata) that utilize the abundant trophic resources at the seeps has led to an increase in the overall assemblage density there. The delta O-13 and delta C-13 values of three species of benthic foraminifera - Gyroidinoides laevigatus, Globocassidulina subglobosa, and Uvigerina peregrina - and the planktonic species Globorotalia menardii were acquired from all three cores. The benthic species from methane seeps yield delta C-13 values of 0.1 to 4.2 (parts per thousand VPDB), that are distinctly more C-13-depleted relative to the delta C-13 of 0.4 to -1.0 (%,,VPDB) at the control (off seep) site. The species from a mussel-bed site exhibit more negative delta C-13 values than those from microbial mats, possibly reflecting different food sources and higher rate of anaerobic oxidation of methane. The positive delta C-13 values in the paired planktonic species suggest that authigenic carbonate precipitation did not overprint the observed C-13 depletions. Hence the probable cause of negative delta C-13 of benthic foraminifera is primary calcification from Dissolved Inorganic Carbon (DIC) containing mixed carbon fractions from (a) highly C-13-depleted, microbially-oxidized methane and (b) a seawater source. (C) 2014 Elsevier B.V. All rights reserved.