Plant rhizosphere oxidation reduces methane production and emission in rewetted peatlands

The global loss of peatlands, by drainage or peat extraction, has encouraged measures to restore these ecosystems and their function as carbon sinks. However, there is a potential of high emissions of the potent greenhouse gas CH4 from restored peatlands. Vascular plants, which often dominate restor...

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Bibliographic Details
Published in:Soil biology & biochemistry 2018-10, Vol.125, p.125-135
Main Authors: Agethen, Svenja, Sander, Michael, Waldemer, Carolin, Knorr, Klaus-Holger
Format: Article
Language:English
Subjects:
Mediated electrochemical reduction and oxidation
Peatlands
Restoration
Rhizosphere
Suppression of methanogenesis
Terminal electron acceptors
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Summary:The global loss of peatlands, by drainage or peat extraction, has encouraged measures to restore these ecosystems and their function as carbon sinks. However, there is a potential of high emissions of the potent greenhouse gas CH4 from restored peatlands. Vascular plants, which often dominate restored sites, play a key role in determining the amount of emitted CH4: The plants can either fuel methanogenesis by supplying labile carbon or attenuate methanogenesis by transferring oxygen into the rhizosphere. To quantify the net effect of these counteracting processes, we tested in a two-pronged approach CH4 production, emission, and the underlying processes in (1.) monoliths of three different restored cutover peatlands and in (2.) mesocosms with Eriophorum vaginatum, E. angustifolium and Juncus effusus versus controls with Sphagna and bare peat. Despite waterlogged, and thus persisting anoxic conditions, concentrations of dissolved CH4 remained close to zero in all tested monoliths. We ascribe this finding to two factors: The poor decomposability of the peat material, as determined in anoxic incubations, and the availability of alternative electron acceptors that sustained anaerobic respiration and competitively suppressed methanogenesis. While inorganic electron acceptor pools were small and rapidly diminished, dissolved organic matter provided constant electron acceptor capacity, indicating that reducible moieties in the organic matter were continuously re-oxidized in the rhizosphere of all tested vascular plant species. This continuous re-oxidation of the dissolved organic matter correlated with plant growth rates (R2 = 0.6–0.8), suggesting that supply of oxygen through the aerenchyma of plant roots regenerated electron acceptor capacity in the rhizosphere. Vascular plants may have differential effects on the net ecosystem exchange, however, our findings suggest that CH4 concentrations and emissions may remain low in restored cutover peatlands for months to years. Thus, waterlogging and vascular plant cover of degraded cutover peatlands does not necessarily create hot-spots of CH4 emissions. •E. vaginatum, E. angustifolium and J. effusus suppressed methanogenesis in rewetted cutover peatlands.•Suppression of methanogenesis was positively linked to plant growth rates.•Suppression of methanogenesis was only detectable by the electron acceptor capacity of dissolved organic matter.
ISSN:0038-0717
1879-3428
DOI:10.1016/j.soilbio.2018.07.006