Water column methane oxidation adjacent to an area of active hydrate dissociation, Eel river Basin
about
Methane seep carbonates yield clumped isotope signatures out of equilibrium with formation temperaturesOcean methane hydrates as a slow tipping point in the global carbon cycleMethane Hydrates in Quaternary Climate Change: The Clathrate Gun HypothesisTimescales of methane seepage on the Norwegian margin following collapse of the Scandinavian Ice SheetTaking action against ocean acidification: a review of management and policy options.Distributions of putative aerobic methanotrophs in diverse pelagic marine environments.A persistent oxygen anomaly reveals the fate of spilled methane in the deep Gulf of Mexico.Carbonate-hosted methanotrophy represents an unrecognized methane sink in the deep sea.Microbial eukaryotic distributions and diversity patterns in a deep-sea methane seep ecosystem.Propane respiration jump-starts microbial response to a deep oil spill.Aerobic methane oxidation and methanotroph community composition during seasonal stratification in Mono Lake, California (USA).Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance.Aerobic and Anaerobic Methanotrophic Communities Associated with Methane Hydrates Exposed on the Seafloor: A High-Pressure Sampling and Stable Isotope-Incubation Experiment.Freshwater lake to salt-water sea causing widespread hydrate dissociation in the Black Sea.Escape of methane gas from the seabed along the West Spitsbergen continental marginTemporal constraints on hydrate-controlled methane seepage off SvalbardMarine microbes rapidly adapt to consume ethane, propane, and butane within the dissolved hydrocarbon plume of a natural seepMethane oxidation in the eastern tropical North Pacific Ocean water columnCompositional variability and air-sea flux of ethane and propane in the plume of a large, marine seep field near Coal Oil Point, CAMethanotrophic bacteria occupy benthic microbial mats in shallow marine hydrocarbon seeps, Coal Oil Point, CaliforniaRising Arctic Ocean temperatures cause gas hydrate destabilization and ocean acidificationThe interaction of climate change and methane hydratesA conduit dilation model of methane venting from lake sedimentsCarbon cycling fed by methane seepage at the shallow Cumberland Bay, South Georgia, sub-AntarcticMicrobial methanogenesis in the sulfate-reducing zone of surface sediments traversing the Peruvian marginModeling the fate of methane hydrates under global warmingOcean oxygen depletion due to decomposition of submarine methane hydrateMagnitude and oxidation potential of hydrocarbon gases released from the BP oil well blowoutAtlantic bubble bathControls on methane concentration and stable isotope (δ2H-CH4andδ13C-CH4) distributions in the water columns of the Black Sea and Cariaco BasinMethane Hydrate Instability: A View from the Palaeogene
P2860
Q28595802-74301D42-2FD8-4F3D-8085-CDB20E3C19B4Q28756534-DF9D3377-4D0D-48AA-84F7-3CBD16F6D31AQ29305335-96B0E7BF-A6A6-41B0-8484-D35DAFB0C82AQ30383212-B133CB42-9DDF-49E2-9987-EB60788A763BQ30658067-8B7FF74B-9521-4C3B-BA2C-8C82A4DEC54CQ33530621-9F5F437B-E549-424D-BF95-C998ED0E55B7Q34157905-B0FCDB41-10D7-41CB-8FF1-195BFD1571FFQ35330636-598DFEE3-0257-406B-A19E-0956F6EBA7EDQ35867918-4A77C02A-7E9F-4C6E-A51B-A59390A20254Q42905374-B96294C8-850F-4B09-8C7F-3CE9E09DD9FBQ44109089-88C83A44-F0FE-442D-B4CE-F86A8A64066DQ46536758-5D2F3D6A-40B0-4E77-9455-F074D0955D40Q47192212-BD5D0C4F-1029-4601-B9E5-B1AD0F3E60D6Q47724078-17F20325-3464-4041-BD5A-042CDD8C812DQ56771467-A03AD2EE-969F-4281-A447-DB9D52B31E3FQ57115102-7B13C42A-B17C-488D-8AB3-561EE0FE1577Q57235075-2827E3CA-2F4A-4AD3-B090-6B610C3916B5Q57235078-3D546DDC-D948-4EA3-98B4-9BD8A1F61346Q57235119-A84D0C38-233B-43B6-872C-1D67FD1C2078Q57235143-0D37C0A9-F182-488E-B458-78B05F5A2B01Q57818646-47BAECAB-B7A0-4A77-9AC6-5C637E97AF09Q57851335-0AF8D9FC-174B-42A5-AAB1-94A33F79C671Q57851408-571B5F68-6A74-4875-BDF4-19D77C6DB7F3Q57859400-15C9EBEC-9A25-4B8C-ADD2-0B31657B76B4Q57889327-DF00C4CC-39C8-42D4-A2A3-5FE297FA1238Q58054411-16C22E5E-277D-4B21-AA82-A2162059DF26Q58066549-9A46B512-2233-434C-B6B1-2F4200E92361Q58074035-4FCADCD2-F1F0-4CE3-90DC-D7D59280FD5BQ58084499-2FC86605-869A-479A-947A-61CDBE2F7BB5Q58084531-EAA7EC91-54F7-43A3-87AD-98031495636EQ58422103-C6890C63-CA29-4A96-ADD2-1A8B44A1C52C
P2860
Water column methane oxidation adjacent to an area of active hydrate dissociation, Eel river Basin
description
article
@en
im August 2001 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в серпні 2001
@uk
name
Water column methane oxidation ...... dissociation, Eel river Basin
@en
Water column methane oxidation ...... dissociation, Eel river Basin
@nl
type
label
Water column methane oxidation ...... dissociation, Eel river Basin
@en
Water column methane oxidation ...... dissociation, Eel river Basin
@nl
prefLabel
Water column methane oxidation ...... dissociation, Eel river Basin
@en
Water column methane oxidation ...... dissociation, Eel river Basin
@nl
P2093
P1476
Water column methane oxidation ...... dissociation, Eel river Basin
@en
P2093
David L Valentine
Douglas C Blanton
Miriam Kastner
William S Reeburgh
P304
P356
10.1016/S0016-7037(01)00625-1
P577
2001-08-01T00:00:00Z