Rapid methane oxidation in a landfill cover soil

Methane oxidation rates observed in a topsoil covering a retired landfill are the highest reported (45 g m-2 day-1) for any environment. This microbial community had the capacity to rapidly oxidize CH4 at concentrations ranging from 1 ppm (microliters per liter) first-order rate constant [k]10(4) pp...

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Bibliographic Details
Published in:Applied and Environmental Microbiology 1990-11, Vol.56 (11), p.3405-3411
Main Authors: Whalen, S.C. (University of Alaska, Fairbanks, AK), Reeburgh, W.S, Sandbeck, K.A
Format: Article
Language:English
Subjects:
ALKANES
Animal, plant and microbial ecology
BACTERIA
BIOGEOCHEMISTRY
Biological and medical sciences
CAPA ARABLE DEL SUELO
CHEMICAL REACTIONS
CHEMISTRY
COUCHE ARABLE
ELIMINACION DE DESECHOS
ELIMINATION DES DECHETS
ENVIRONMENTAL SCIENCES
Fundamental and applied biological sciences. Psychology
General Microbial Ecology
GEOCHEMISTRY
HYDROCARBONS
MANAGEMENT
METANO
METHANE
Microbial ecology
MICROORGANISME
MICROORGANISMOS
MICROORGANISMS
MOISTURE
ORGANIC COMPOUNDS
OXIDACION
OXIDATION
OXYDATION
SANITARY LANDFILLS
Soil
SOILS
TERRE
TIERRAS
WASTE DISPOSAL
WASTE MANAGEMENT 540220 > Environment, Terrestrial-- Chemicals Monitoring & Transport-- (1990-)
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Summary:Methane oxidation rates observed in a topsoil covering a retired landfill are the highest reported (45 g m-2 day-1) for any environment. This microbial community had the capacity to rapidly oxidize CH4 at concentrations ranging from 1 ppm (microliters per liter) first-order rate constant [k]10(4) ppm (k = -2.37 h-1). The physiological characteristics of a methanotroph isolated from the soil (characteristics determined in aqueous medium) and the natural population, however, were similar to those of other natural populations and cultures: the Q10 and optimum temperature were 1.9 and 31 degrees C, respectively, the apparent half-saturation constant was 2.5 to 9.3 micromole, and 19 to 69% of oxidized CH4 was assimilated into biomass. The CH4 oxidation rate of this soil under waterlogged (41% [wt/vol] H2O) conditions, 6.1 mg liter-1 day-1, was near rates reported for lake sediment and much lower than the rate of 116 mg liter-1 day-1 in the same soil under moist (11% H2O) conditions. Since there are no large physiological differences between this microbial community and other CH4 oxidizers, we attribute the high CH4 oxidation rate in moist soil to enhanced CH4 transport to the microorganisms; gas-phase molecular diffusion is 10(4)-fold faster than aqueous diffusion. These high CH4 oxidation rates in moist soil have implications that are important in global climate change. Soil CH4 oxidation could become a negative feedback to atmospheric CH4 increases (and warming) in areas that are presently waterlogged but are projected to undergo a reduction in summer soil moisture
ISSN:0099-2240
1098-5336
DOI:10.1128/aem.56.11.3405-3411.1990