Trapped Methane Volume and Potential Effects on Methane Ebullition in a Northern Peatland

Trapped Methane Volume and Potential Effects on Methane Ebullition in a Northern Peatland

A novel way of estimating the gas bubble volume in the floating mat sediment of a peatland was developed at Thoreau's Bog in Concord, Massachuasetts. Statistically significant relationships between the buoyancy of the floating Sphagnum mat and atmospheric pressure were observed, and these relat...

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Bibliographic Details
Published in:Limnology and oceanography Vol. 41; no. 7; pp. 1375 - 1383
Main Authors: Fechner-Levy, Elizabeth J., Hemond, Harold F.
Format: Journal Article
Language:English
Published: Waco, TX American Society of Limnology and Oceanography 01-11-1996
Subjects:
Atmospheric pressure
Bogs
Boiling
Bubbles
Buoyancy
Earth sciences
Earth, ocean, space
Exact sciences and technology
Freshwater
Marine
Marine and continental quaternary
Methane
Peat
Peatlands
Sediments
Sphagnum
Surficial geology
Water tables
United States
Massachusetts
USA, Massachusetts, Concord, Thoreau's Bog
ANW, USA, Massachusetts
USA, Massachusetts, Concord
atmosphere
Musci
Plantae
water table
water pressure
North America
buoyancy
bryophytes
atmospheric pressure
Sphagnum
peat bogs
methane
temperature
flux
growth
statistical analysis
peat
sediment volume
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Summary:A novel way of estimating the gas bubble volume in the floating mat sediment of a peatland was developed at Thoreau's Bog in Concord, Massachuasetts. Statistically significant relationships between the buoyancy of the floating Sphagnum mat and atmospheric pressure were observed, and these relationships were used to estimate the gas bubble volume. The mass of CH4stored in gas bubbles is estimated to be as much as 3 times the mass of dissolved CH4, depending on the time of year. The gas bubble volume is frequently large enough to serve as a significant buffer between microbial production of CH4and the release of CH4to the atmosphere. Changes in atmospheric pressure, temperature, and water-table elevation may result in modulation of the ebullitive CH4flux. Periods of rapidly rising atmospheric pressure or equivalent pressure changes due to water-table elevation are capable of arresting bubble volume growth, thereby halting CH4ebullition. Periods of rapid cooling of the bog could also temporarily halt ebullition, as thermally induced contraction of bubbles and dissolution of CH4offset bubble volume growth due to methanogenesis.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0024-3590
1939-5590
DOI:10.4319/lo.1996.41.7.1375