Getting to the Root of Plant‐Mediated Methane Emissions and Oxidation in a Thermokarst Bog

Vascular plants are important in the wetland methane cycle, but their effect on production, oxidation, and transport has high uncertainty, limiting our ability to predict emissions. In a permafrost‐thaw bog in Interior Alaska, we used plant manipulation treatments, field‐deployed planar optical oxyg...

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Bibliographic Details
Published in:Journal of geophysical research. Biogeosciences 2020-11, Vol.125 (11), p.n/a
Main Authors: Turner, Jesse C., Moorberg, Colby J., Wong, Andrea, Shea, Kathleen, Waldrop, Mark P., Turetsky, Merritt R., Neumann, Rebecca B.
Format: Article
Language:English
Subjects:
aerenchyma
Atmosphere
Bogs
Carbon dioxide
Carex
Carex vascular vegetation
Climate change
DNA
DNA damage
Emissions
Exudates
Exudation
Flowers & plants
GEOSCIENCES
Greenhouse effect
Greenhouse gases
Identification methods
Mass balance
Methane
Methanotrophic bacteria
Microorganisms
Mimicry
Oxidation
Oxygen
Oxygen consumption
Oxygen probes
Permafrost
Plant roots
Plants
Relative abundance
root exudates
Seasons
Silicones
Soil
Soil microorganisms
Soils
Thawing
thermokarst
Transport
Tubes
Vegetation
wetland
Wetlands
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Summary:Vascular plants are important in the wetland methane cycle, but their effect on production, oxidation, and transport has high uncertainty, limiting our ability to predict emissions. In a permafrost‐thaw bog in Interior Alaska, we used plant manipulation treatments, field‐deployed planar optical oxygen sensors, direct measurements of methane oxidation, and microbial DNA analyses to disentangle mechanisms by which vascular vegetation affect methane emissions. Vegetation operated on top of baseline methane emissions, which varied with proximity to the thawing permafrost margin. Emissions from vegetated plots increased over the season, resulting in cumulative seasonal methane emissions that were 4.1–5.2 g m−2 season−1 greater than unvegetated plots. Mass balance calculations signify these greater emissions were due to increased methane production (3.0–3.5 g m−2 season−1) and decreased methane oxidation (1.1–1.6 g m−2 season−1). Minimal oxidation occurred along the plant‐transport pathway, and oxidation was suppressed outside the plant pathway. Our data indicate suppression of methane oxidation was stimulated by root exudates fueling competition among microbes for electron acceptors. This contention is supported by the fact that methane oxidation and relative abundance of methanotrophs decreased over the season in the presence of vegetation, but methane oxidation remained steady in unvegetated treatments; oxygen was not detected around plant roots but was detected around silicone tubes mimicking aerenchyma; and oxygen injection experiments suggested that oxygen consumption was faster in the presence of vascular vegetation. Root exudates are known to fuel methane production, and our work provides evidence they also decrease methane oxidation. Plain Language Summary Methane is a greenhouse gas with a greater ability to warm the earth than carbon dioxide. Wetlands are the largest natural source of methane to the atmosphere. To understand future climate change, scientists need to predict the amount of methane released from wetlands. Many factors affect the amount of methane generated by soil microbes (called methane production) and how much methane is released into the atmosphere (called methane emission). Methane traveling through soils can also get converted to carbon dioxide through methane oxidation. Wetland plants influence production, transport, and oxidation of methane, but studies disagree on their overall effect on emissions. In this study, we used multipl
ISSN:2169-8953
2169-8961
DOI:10.1029/2020JG005825