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Mineral Stabilization Slows Losses of Peatland Carbon Following Long-Term Drainage for Agriculture.

Accepted version
Peer-reviewed

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Abstract

Cultivated peatlands are a major CO2 emission source, but the processes that regulate the decomposition of drained peat are debated, especially as drained peat becomes increasingly shallow. Many cultivated peatlands are underlain by a mineral soil layer. Surface subsidence, oxidation and tillage reduce the peat thickness, which intermixes peat with minerals as peat is lost. A key question is whether this mixing can reduce emissions by making soil organic carbon (SOC) more stable by transforming particulate organic carbon (POC)-which dominates the carbon stock in deep drained peatlands and is readily accessible to microbial decomposers-into mineral-associated organic carbon (MAOC), which is less accessible to decomposers. To explore this question, we surveyed ten sites across the East Anglian Fens in England, a once extensive (~3900 km2) peatland landscape that has been drained for cultivation since the mid-seventeenth century. We used variation in cultivation to establish a peat loss gradient to evaluate how topsoil SOC (0-40 cm) and its forms change as peat is lost. As the peat was lost, the soils became rich in minerals (rising from 46% to 88% silt+clay content), resulting in an initial 11-fold rise in newly-formed MAOC, but a monotonic decline and near-total loss of POC. POC turnover times were 3158 ± 62 years, indicative of peat, and POC was always older than MAOC; consequently, microbially-processed peat along with gradual contributions of recently fixed carbon were sources of MAOC. A four-month laboratory incubation showed that the MAOC:POC ratio was negatively correlated with respiration. We conclude that long-term carbon retention via MAOC formation has the potential to reduce carbon loss from degraded, mineral-mixed peatlands. However, because this MAOC pool is itself vulnerable to loss under continued agricultural drainage, this mechanism is expected to slow rather than halt long-term soil carbon loss from drained peatlands.

Description

Journal Title

Glob Chang Biol

Conference Name

Journal ISSN

1354-1013
1365-2486

Volume Title

Publisher

Wiley

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Except where otherwised noted, this item's license is described as Attribution 4.0 International
Sponsorship
NERC (NE/W00495X/1)
AFAP was funded by UKSA grant UKSAG23_0093-008, and UKRI grants NE/W00495X/1, BB/Z51634X/1 and EP/X042863/1. DAC, KJF, CEV and RM were funded by UKRI grant Cambridge Centre for Landscape Regeneration, NE/W00495X/1. Radiocarbon analyses were funded by the NERC National Environmental Isotope Facility award number 2690.1023.