Sources of biogenic methane to form marine gas hydrates: In situ production or upward migration?

Potential sources of biogenic methane in the Carolina Continental Rise -- Blake Ridge sediments have been examined. Two models were used to estimate the potential for biogenic methane production: (1) construction of sedimentary organic carbon budgets, and (2) depth extrapolation of modern microbial...

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Bibliographic Details
Main Authors: Paull, C.K., Ussler, W. III, Borowski, W.S.
Language:unknown
Published: 2008
Subjects:
03 NATURAL GAS
CONTINENTAL SHELF
NATURAL GAS HYDRATE DEPOSITS
RESOURCE ASSESSMENT
METHANE
BIOSYNTHESIS
NORTH CAROLINA
SOUTH CAROLINA
RESOURCE POTENTIAL
GAS HYDRATES
STABILITY
MIGRATION
METHANOGENIC BACTERIA
SEDIMENTS
Methane hydrate
Online Access:http://www.osti.gov/servlets/purl/10185837
https://www.osti.gov/biblio/10185837
https://doi.org/10.2172/10185837
Description
Summary:Potential sources of biogenic methane in the Carolina Continental Rise -- Blake Ridge sediments have been examined. Two models were used to estimate the potential for biogenic methane production: (1) construction of sedimentary organic carbon budgets, and (2) depth extrapolation of modern microbial production rates. While closed-system estimates predict some gas hydrate formation, it is unlikely that >3% of the sediment volume could be filled by hydrate from methane produced in situ. Formation of greater amounts requires migration of methane from the underlying continental rise sediment prism. Methane may be recycled from below the base of the gas hydrate stability zone by gas hydrate decomposition, upward migration of the methane gas, and recrystallization of gas hydrate within the overlying stability zone. Methane bubbles may also form in the sediment column below the depth of gas hydrate stability because the methane saturation concentration of the pore fluids decreases with increasing depth. Upward migration of methane bubbles from these deeper sediments can add methane to the hydrate stability zone. From these models it appears that recycling and upward migration of methane is essential in forming significant gas hydrate concentrations. In addition, the depth distribution profiles of methane hydrate will differ if the majority of the methane has migrated upward rather than having been produced in situ.

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