Net soil carbon balance in afforested peatlands and separating autotrophic and heterotrophic soil CO.sub.2 effluxes

Peatlands are a significant global carbon (C) store, which can be compromised by drainage and afforestation. Quantifying the rate of C loss from peat soils under forestry is challenging, as soil CO.sub.2 efflux includes both CO.sub.2 produced from heterotrophic peat decomposition and CO.sub.2 produc...

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Veröffentlicht in:	Biogeosciences 2022-01, Vol.19 (2), p.313
Hauptverfasser:	Hermans, Renée, McKenzie, Rebecca, Andersen, Roxane, Teh, Yit Arn, Cowie, Neil, Subke, Jens-Arne
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Schlagworte:	Carbon content Peat Peat-bogs Soils
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creator	Hermans, Renée McKenzie, Rebecca Andersen, Roxane Teh, Yit Arn Cowie, Neil Subke, Jens-Arne
description	Peatlands are a significant global carbon (C) store, which can be compromised by drainage and afforestation. Quantifying the rate of C loss from peat soils under forestry is challenging, as soil CO.sub.2 efflux includes both CO.sub.2 produced from heterotrophic peat decomposition and CO.sub.2 produced by tree roots and associated fungal networks (autotrophic respiration). We experimentally terminated autotrophic below-ground respiration in replicated forest plots by cutting through all living tree roots (trenching) and measured soil surface CO.sub.2 flux, litter input, litter decay rate, and soil temperature and moisture over 2 years. Decomposition of cut roots was measured and CO.sub.2 fluxes were corrected for this, which resulted in a large change in the fraction heterotrophic : autotrophic flux, suggesting that even 2 years after trenching decaying root biomass makes significant contributions to the CO.sub.2 flux. Annual peat decomposition (heterotrophic CO.sub.2 flux) was 115 Â± 16 g C m.sup.-2 yr.sup.-1, representing ca. 40 % of total soil respiration. Decomposition of needle litter is accelerated in the presence of an active rhizosphere, indicating a priming effect by labile C inputs from roots. This suggests that our estimates of peat mineralization in our trenched plots are conservative and underestimate overall rates of peat C loss. Considering also input of litter from trees, our results indicate that the soils in these 30-year-old drained and afforested peatlands are a net sink for C, since substantially more C enters the soil organic matter than is decomposed heterotrophically. This study does not account for fluvial C fluxes, which represent a small flux compared to the CO.sub.2 soil efflux; further, root litter and exudate deposition could be a significant C source that is only partially sampled by our approach, adding to these plantations being a potential carbon sink. However, the C balance for these soils should be taken over the lifespan of the trees, in order to determine if the soils under these drained and afforested peatlands are a sustained sink of C or become a net source over longer periods of forestry.
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Decomposition of needle litter is accelerated in the presence of an active rhizosphere, indicating a priming effect by labile C inputs from roots. This suggests that our estimates of peat mineralization in our trenched plots are conservative and underestimate overall rates of peat C loss. Considering also input of litter from trees, our results indicate that the soils in these 30-year-old drained and afforested peatlands are a net sink for C, since substantially more C enters the soil organic matter than is decomposed heterotrophically. This study does not account for fluvial C fluxes, which represent a small flux compared to the CO.sub.2 soil efflux; further, root litter and exudate deposition could be a significant C source that is only partially sampled by our approach, adding to these plantations being a potential carbon sink. 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Quantifying the rate of C loss from peat soils under forestry is challenging, as soil CO.sub.2 efflux includes both CO.sub.2 produced from heterotrophic peat decomposition and CO.sub.2 produced by tree roots and associated fungal networks (autotrophic respiration). We experimentally terminated autotrophic below-ground respiration in replicated forest plots by cutting through all living tree roots (trenching) and measured soil surface CO.sub.2 flux, litter input, litter decay rate, and soil temperature and moisture over 2 years. Decomposition of cut roots was measured and CO.sub.2 fluxes were corrected for this, which resulted in a large change in the fraction heterotrophic : autotrophic flux, suggesting that even 2 years after trenching decaying root biomass makes significant contributions to the CO.sub.2 flux. Annual peat decomposition (heterotrophic CO.sub.2 flux) was 115 Â± 16 g C m.sup.-2 yr.sup.-1, representing ca. 40 % of total soil respiration. Decomposition of needle litter is accelerated in the presence of an active rhizosphere, indicating a priming effect by labile C inputs from roots. This suggests that our estimates of peat mineralization in our trenched plots are conservative and underestimate overall rates of peat C loss. Considering also input of litter from trees, our results indicate that the soils in these 30-year-old drained and afforested peatlands are a net sink for C, since substantially more C enters the soil organic matter than is decomposed heterotrophically. This study does not account for fluvial C fluxes, which represent a small flux compared to the CO.sub.2 soil efflux; further, root litter and exudate deposition could be a significant C source that is only partially sampled by our approach, adding to these plantations being a potential carbon sink. However, the C balance for these soils should be taken over the lifespan of the trees, in order to determine if the soils under these drained and afforested peatlands are a sustained sink of C or become a net source over longer periods of forestry.</abstract><pub>Copernicus GmbH</pub><tpages>313</tpages></addata></record>
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subjects	Carbon content Peat Peat-bogs Soils
title	Net soil carbon balance in afforested peatlands and separating autotrophic and heterotrophic soil CO.sub.2 effluxes
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