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More is not always better: peat moss mixtures slightly enhance peatland stability.

Bjorn J M RobroekGiulia DevileeYvet TelgenkampCarina HärlinMagdalena N SteeleJanna M BarelLeon P M Lamers
Published in: Proceedings. Biological sciences (2024)
Terrestrial wetland ecosystems challenge biodiversity-ecosystem function theory, which generally links high species diversity to stable ecosystem functions. An open question in ecosystem ecology is whether assemblages of co-occurring peat mosses contribute to the stability of peatland ecosystem processes. We conducted a two-species ( Sphagnum cuspidatum , Sphagnum medium ) replacement series mesocosm experiment to evaluate the resistance, resilience, and recovery rates of net ecosystem CO 2 exchange (NEE) under mild and deep water table drawdown. Our results show a positive effect of mild water table drawdown on NEE with no apparent role for peat moss mixture. Our study indicates that the carbon uptake capacity by peat moss mixtures is rather resilient to mild water table drawdown, but seriously affected by deeper drought conditions. Co-occurring peat moss species seem to enhance the resilience of the carbon uptake function (i.e. ability of NEE to return to pre-perturbation levels) of peat moss mixtures only slightly. These findings suggest that assemblages of co-occurring Sphagnum mosses do only marginally contribute to the stability of ecosystem functions in peatlands under drought conditions. Above all, our results highlight that predicted severe droughts can gravely affect the sink capacity of peatlands, with only a small extenuating role for peat moss mixtures.
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