Biological conversion of coal gas to methane

Barik, S; Vega, J L; Clausen, E C; Gaddy, J L

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Biological conversion of coal gas to methane

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Abstract

Biological conversion of low-Btu coal synthesis gas to higher Btu methane was demonstrated using both pure co-cultures and/or adapted-mixed anaerobic bacteria. Peptostreptococcus productus metabolized coal gas to mainly acetate and CO/sub 2/. The co-cultures containing methanogens converted these products to methane. In mixed culture studies, CH/sub 4/ and small amounts of acetate were produced. Reactor studies using stirred-tank and immobilized cell reactors exhibited excellent potential to convert CO, CO/sub 2/ and H/sub 2/ to methane at higher gas flow rates. Gas retention times ranging from 0.7 to 2 hours and high agitation were required for 90 percent CO conversion in these systems. This paper also illustrates the potential of biological methanation and demonstrates the need for good mass transfer in converting gas phase substrates. 21 refs., 1 fig., 7 tabs.

Authors:

Barik, S; Vega, J L; Clausen, E C; Gaddy, J L

Publication Date:

Aug 01, 1988

Product Type:

Conference

Report Number:

CONF-870523-

Reference Number:

CLA-88-110315; EDB-88-175673

Resource Relation:

Journal Name: Appl. Biochem. Biotechnol.; (United States); Journal Volume: 18; Conference: 9. symposium on biotechnology for fuels and chemicals, Boulder, CO, USA, 5 May 1987

Subject:

01 COAL, LIGNITE, AND PEAT; METHANATION; BACTERIA; SYNTHESIS GAS; BIOCONVERSION; ACETATES; ANAEROBIC CONDITIONS; BENCH-SCALE EXPERIMENTS; BIOCHEMICAL REACTION KINETICS; CARBON DIOXIDE; CARBON MONOXIDE; CELL CULTURES; COAL GAS; MASS TRANSFER; METABOLISM; METHANE; METHANOGENIC BACTERIA; MICROORGANISMS; ALKANES; CARBON COMPOUNDS; CARBON OXIDES; CARBOXYLIC ACID SALTS; CHALCOGENIDES; CHEMICAL REACTIONS; FLUIDS; GASES; HYDROCARBONS; KINETICS; ORGANIC COMPOUNDS; OXIDES; OXYGEN COMPOUNDS; REACTION KINETICS; 010408* - Coal, Lignite, & Peat- C1 Processes- (1987-)

OSTI ID:

6820757

Research Organizations:

University of Arkansas, Fayetteville (USA). Dept. of Chemical Engineering

Country of Origin:

United States

Language:

English

Other Identifying Numbers:

Journal ID: CODEN: ABIBD

Submitting Site:

CLA

Size:

Pages: 379-392

Announcement Date:

May 13, 2001

Citation Formats

Barik, S, Vega, J L, Clausen, E C, and Gaddy, J L. Biological conversion of coal gas to methane. United States: N. p., 1988. Web.

Barik, S, Vega, J L, Clausen, E C, & Gaddy, J L. Biological conversion of coal gas to methane. United States.

Barik, S, Vega, J L, Clausen, E C, and Gaddy, J L. 1988. "Biological conversion of coal gas to methane." United States.

@misc{etde_6820757,
title = {Biological conversion of coal gas to methane}
author = {Barik, S, Vega, J L, Clausen, E C, and Gaddy, J L}
abstractNote = {Biological conversion of low-Btu coal synthesis gas to higher Btu methane was demonstrated using both pure co-cultures and/or adapted-mixed anaerobic bacteria. Peptostreptococcus productus metabolized coal gas to mainly acetate and CO/sub 2/. The co-cultures containing methanogens converted these products to methane. In mixed culture studies, CH/sub 4/ and small amounts of acetate were produced. Reactor studies using stirred-tank and immobilized cell reactors exhibited excellent potential to convert CO, CO/sub 2/ and H/sub 2/ to methane at higher gas flow rates. Gas retention times ranging from 0.7 to 2 hours and high agitation were required for 90 percent CO conversion in these systems. This paper also illustrates the potential of biological methanation and demonstrates the need for good mass transfer in converting gas phase substrates. 21 refs., 1 fig., 7 tabs.}
journal = []
volume = {18}
place = {United States}
year = {1988}
month = {Aug}
}

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