FN Archimer Export Format PT J TI Variability in gas and solute fluxes through deep-sea chemosynthetic ecosystems inhabited by vesicomyid bivalves in the gulf of Guinea BT AF KHRIPOUNOFF, Alexis CAPRAIS, Jean-Claude DECKER, Carole ESSIRARD, Mikael LE BRUCHEC, Julie NOEL, Philippe OLU, Karine AS 1:1;2:1;3:1;4:1;5:1;6:1;7:1; FF 1:PDG-REM-EEP-LEP;2:PDG-REM-EEP-LEP;3:PDG-REM-EEP-LEP;4:PDG-REM-EEP-LEP;5:PDG-REM-EEP-LEP;6:PDG-REM-EEP-LEP;7:PDG-REM-EEP-LEP; C1 IFREMER, Ctr Brest, Dept REW EEP, Lab Environm Profond, F-29280 Plouzane, France. C2 IFREMER, FRANCE SI BREST SE PDG-REM-EEP-LEP IN WOS Ifremer jusqu'en 2018 IF 2.684 TC 12 UR https://archimer.ifremer.fr/doc/00226/33746/32160.pdf LA English DT Article CR WACS BO Pourquoi pas ? DE ;Benthic chamber;Cold-seep ecosystem;Reduced sediment;Gas fluxes;Vesicomyid bivalves;Gulf of Guinea AB We have studied two species of vesicomyid bivalves inhabiting different areas of sulfide-rich sediments in association with methane seepage at two pockmarks located at about 650 m and 3150 m depth, respectively, along the Gabon-Congo margin, and organic-rich sediments in the deepest zone (4950 m depth) of the Congo deep-sea fan. Benthic chambers Calmar were deployed on three study sites to assess gas and solute exchanges at the water-sediment interface. We recorded in situ measurements of oxygen, total carbon dioxide, ammonium, methane, and sulfide in two clam beds at each site. At all sites, irrespective of which the vesicomyid species are present, oxygen consumption was high and variable (28–433 mmol m−2 d−1) as was total carbon dioxide emission (36–1857 mmol m−2 d−1). Consequently, the respiratory coefficient also varied greatly, ranging from 0.2 to 5.4. The observed gas and solute fluxes were attributed primarily to the respiration of clams, but microbial and geochemical processes in the sediment may be also responsible for some of the variation among sites. Ammonium production (7.5–71.8 mmol m−2 d−1) was associated predominantly with nitrogen excretion resulting from vesicomyid metabolism. The O:N index ranged from 2 to 17 indicating that the vesicomyid clams, living in symbiosis with bacteria, have a protein-based metabolism. The cold-seep and organic-rich sediment ecosystems were fuelled by methane expelled from the sediment; methane emission varied from 1.8 to 139 mmol m−2d−1, independently of bivalve biomass. Significant sulfide emission from the sediment was observed only at the shallowest station (156 mmol m−2 d−1). Our in situ measurements confirm that the vesicomyid bivalves have a high capacity for growth and survival across a large gradient of methane and hydrogen sulfide fluxes that occur at 700 m to 5000 m depth. PY 2015 PD JAN SO Deep-sea Research Part I-oceanographic Research Papers SN 0967-0637 PU Pergamon-elsevier Science Ltd VL 95 UT 000348628100011 BP 122 EP 130 DI 10.1016/j.dsr.2014.10.013 ID 33746 ER EF