The effects of snowpack properties and plant strategies on litter decomposition during winter in subalpine meadows

Aims Climate-induced changes in snow cover are likely to affect cold arctic and alpine ecosystems functioning and major processes such as wintertime plant litter decomposition. However, it remains poorly studied in subalpine systems where the snowpack may be irregular. In this paper we explored the...

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Veröffentlicht in:Plant and soil 2013-02, Vol.363 (1/2), p.215-229
Hauptverfasser: Saccone, Patrick, Morin, Samuel, Baptist, Florence, Bonneville, Jean-Marc, Colace, Marie-Pascale, Domine, Florent, Faure, Mathieu, Geremia, Roberto, Lochet, Jonathan, Poly, Franck, Lavorel, Sandra, Clément, Jean-Christophe
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Sprache:eng
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Zusammenfassung:Aims Climate-induced changes in snow cover are likely to affect cold arctic and alpine ecosystems functioning and major processes such as wintertime plant litter decomposition. However, it remains poorly studied in subalpine systems where the snowpack may be irregular. In this paper we explored the dynamic of the winter plant litter decomposition process, its magnitude and its relationship with the snowpack properties. Methods In subalpine grasslands of the Central French Alps, we performed a litter bag experiment monitoring over a whole winter the litter decomposition from the exploitative Dactylis glomerata and the conservative Festuca paniculata, under two contiguous experimental sites with snowpacks differing in depth and physical properties. Results Litter decomposition rates were stable during winter and 3-fold higher under deeper and permanent snowpack with higher thermal resistance. Litter quality appeared only significant under thinner snowpack with higher decomposition rates for the exploitative species. A snowpack with higher thermal resistance created an insulating layer promoting the decomposition process. Conclusion These results suggest that the temporal (permanence vs. intermittency) and physical (depth and thermal resistance) characteristics of the snowpack should be considered when studying the response of winter ecosystems functioning to global changes.
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-012-1307-3