Analytical theory relating the depth of the sulfate-methane transition to gas hydrate distribution and saturation

Geochemistry, Geophysics, Geosystems

Volumn 12, Issue 3, 2011, Pages

  Bhatnagar, Gaurav ^a,b   Chatterjee, Sayantan ^a   Chapman, Walter G ^a   Dugan, Brandon ^c   Dickens, Gerald R ^c,d   Hirasaki, George J ^a  

^a Rice University   (United States)

^b Shell Technology and Projects   (United States)

^c RICE UNIVERSITY   (United States)

^d STOCKHOLM UNIVERSITY   (Sweden)

Author keywords

analytical modeling; Cascadia Margin; Gas hydrates; marine sediments; sulfate methane transition

Indexed keywords

ANOXIC SEDIMENTS; CHLORINE COMPOUNDS; ELECTRIC LOGGING; GASES; HYDRATION; MATHEMATICAL MODELS; METHANE; SEDIMENTOLOGY; SUBMARINE GEOLOGY;

ANAEROBIC OXIDATION OF METHANES; ANALYTICAL EXPRESSIONS; ANALYTICAL MODEL; ANALYTICAL MODELING; ANALYTICAL THEORY; CASCADIA; DRILL SITES; EXTERNAL SOURCES; FIRST-ORDER; GAS HYDRATE STABILITY ZONES; GEOLOGIC SETTINGS; HYDRATE DISTRIBUTION; HYDRATE SATURATION; MARINE SEDIMENTS; METHANE FLUXES; METHANE SOLUBILITY; SEA FLOOR; SEDIMENTATION RATES; SITE-SPECIFIC PARAMETERS; STEADY STATE; SULFATE-METHANE TRANSITION; SULFATE-METHANE TRANSITIONS; UPWARD ADVECTION;

GAS HYDRATES;

ADVECTION; ANALYTICAL FRAMEWORK; GAS HYDRATE; MARINE SEDIMENT; METHANE; NUMERICAL MODEL; SATURATION; SEAFLOOR; SEDIMENT CHEMISTRY; SULFATE; THEORETICAL STUDY;

CASCADIA MARGIN; PACIFIC OCEAN;

EID: 79952275072     PISSN: 15252027     EISSN: 15252027     Source Type: Journal    
DOI: 10.1029/2010GC003397     Document Type: Article

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