Long-term suppresion of wetland methane flux following a pulse of simulated acid rain

Vincent Gauci; Nancy Dise; Stephen Blake

doi:10.1029/2005GL022544

Long-term suppresion of wetland methane flux following a pulse of simulated acid rain

Vincent Gauci^*, Nancy Dise, Stephen Blake

^*Corresponding author for this work

Geography, Earth and Environmental Sciences

Research output: Contribution to journal › Article › peer-review

24 Citations (Scopus)

Abstract

Wetlands are a potent source of the radiatively important gas methane (CH₄). Recent findings have, demonstrated that sulfate (SO₄^2-) deposition via acid rain suppresses CH₄ emissions by stimulating competitive exclusion of methanogens by sulfate-reducing microbial populations. Here we report data from a field experiment showing that a finite pulse of simulated acid rain SO₄^2- deposition, as would be expected from a large Icelandic volcanic eruption, continues to suppress CH₄ emissions from wetlands long after the pollution event has ceased. Our analysis of the stoichiometries suggests that 5 years is a minimum CH₄ emission recovery period, with 10 years being a reasonable upper limit. Our findings highlight the long-term impact of acid rain on biospheric output of CH₄ which, for discrete polluting events such as volcanic eruptions, outlives the relatively short-term SO₄^2- aerosol radiative cooling effect.

Original language	English
Pages (from-to)	1-4
Number of pages	4
Journal	Geophysical Research Letters
Volume	32
Issue number	12
DOIs	https://doi.org/10.1029/2005GL022544
Publication status	Published - 28 Jun 2005

ASJC Scopus subject areas

Geophysics
General Earth and Planetary Sciences

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abstract = "Wetlands are a potent source of the radiatively important gas methane (CH4). Recent findings have, demonstrated that sulfate (SO42-) deposition via acid rain suppresses CH4 emissions by stimulating competitive exclusion of methanogens by sulfate-reducing microbial populations. Here we report data from a field experiment showing that a finite pulse of simulated acid rain SO42- deposition, as would be expected from a large Icelandic volcanic eruption, continues to suppress CH4 emissions from wetlands long after the pollution event has ceased. Our analysis of the stoichiometries suggests that 5 years is a minimum CH4 emission recovery period, with 10 years being a reasonable upper limit. Our findings highlight the long-term impact of acid rain on biospheric output of CH4 which, for discrete polluting events such as volcanic eruptions, outlives the relatively short-term SO42- aerosol radiative cooling effect.",

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AU - Dise, Nancy

AU - Blake, Stephen

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AB - Wetlands are a potent source of the radiatively important gas methane (CH4). Recent findings have, demonstrated that sulfate (SO42-) deposition via acid rain suppresses CH4 emissions by stimulating competitive exclusion of methanogens by sulfate-reducing microbial populations. Here we report data from a field experiment showing that a finite pulse of simulated acid rain SO42- deposition, as would be expected from a large Icelandic volcanic eruption, continues to suppress CH4 emissions from wetlands long after the pollution event has ceased. Our analysis of the stoichiometries suggests that 5 years is a minimum CH4 emission recovery period, with 10 years being a reasonable upper limit. Our findings highlight the long-term impact of acid rain on biospheric output of CH4 which, for discrete polluting events such as volcanic eruptions, outlives the relatively short-term SO42- aerosol radiative cooling effect.

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Long-term suppresion of wetland methane flux following a pulse of simulated acid rain

Abstract

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