AI Article Synopsis
- - Several studies indicate that climate warming might increase peat decomposition, but most have focused on summer conditions suited for decomposition.
- - This research examined how warming affects organic matter and microbial activities in two different moisture sites (Bog and Fen) using open-top chambers, finding nuanced effects like increased hydrolytic activity in Bog sites.
- - Despite changes in microbial structure and activity, air warming didn’t significantly alter the composition of water-extractable organic matter, highlighting the complexity of decomposition processes and the need for more detailed, time-sensitive studies.
Article Abstract
Several studies on the impact of climate warming have indicated that peat decomposition/mineralization will be enhanced. Most of these studies deal with the impact of experimental warming during summer when prevalent abiotic conditions are favorable to decomposition. Here, we investigated the effect of experimental air warming by open-top chambers (OTCs) on water-extractable organic matter (WEOM), microbial biomasses and enzymatic activities in two contrasted moisture sites named Bog and Fen sites, the latter considered as the wetter ones. While no or few changes in peat temperature and water content appeared under the overall effect of OTCs, we observed that air warming smoothed water content differences and led to a decrease in mean peat temperature at the warmed Bog sites. This thermal discrepancy between the two sites led to contrasting changes in microbial structure and activities: a rise in hydrolytic activity at the warmed Bog sites and a relative enhancement of bacterial biomass at the warmed Fen sites. These features were not associated with any change in WEOM properties namely carbon and sugar contents and aromaticity, suggesting that air warming did not trigger any shift in OM decomposition. Using various tools, we show that the use of single indicators of OM decomposition can lead to fallacious conclusions. Lastly, these patterns may change seasonally as a consequence of complex interactions between groundwater level and air warming, suggesting the need to improve our knowledge using a high time-resolution approach.
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| http://dx.doi.org/10.1016/j.scitotenv.2014.12.095 | DOI Listing |
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