Evidence for older carbon loss with lowered water tables and changing plant functional groups in peatlands

Evidence for older carbon loss with lowered water tables and changing plant functional groups in peatlands

A small imbalance in plant productivity and decomposition accounts for the carbon (C) accumulation capacity of peatlands. As climate changes, the continuity of peatland net C storage relies on rising primary production to offset increasing ecosystem respiration (ER) along with the persistence of old...

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Veröffentlicht in:Global change biology 2023-02, Vol.29 (3), p.780-793
Hauptverfasser: Stuart, Julia E. M., Tucker, Colin L., Lilleskov, Erik A., Kolka, Randall K., Chimner, Rodney A., Heckman, Katherine A., Kane, Evan S.
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Schlagworte:
Carbon
Carbon dioxide
Carbon Dioxide - analysis
carbon fluxes
Climate change
Decomposition
Decoupling
Ecosystem
ecosystem respiration
Functional groups
Groundwater
Groundwater table
Growing season
histosol
Hydrology
Land use
Mesocosms
mixing models
Peat
Peatlands
Plant communities
Plants
Pore water
Primary production
Productivity
radiocarbon
Respiration
Soil
Storage
Vegetation
Vulnerability
Water depth
Water table
Water table depth
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container_end_page 793
container_issue 3
container_start_page 780
container_title Global change biology
container_volume 29
creator Stuart, Julia E. M.
Tucker, Colin L.
Lilleskov, Erik A.
Kolka, Randall K.
Chimner, Rodney A.
Heckman, Katherine A.
Kane, Evan S.
description A small imbalance in plant productivity and decomposition accounts for the carbon (C) accumulation capacity of peatlands. As climate changes, the continuity of peatland net C storage relies on rising primary production to offset increasing ecosystem respiration (ER) along with the persistence of older C in waterlogged peat. A lowering in the water table position in peatlands often increases decomposition rates, but concurrent plant community shifts can interactively alter ER and plant productivity responses. The combined effects of water table variation and plant communities on older peat C loss are unknown. We used a full‐factorial 1‐m3 mesocosm array with vascular plant functional group manipulations (Unmanipulated Control, Sedge only, and Ericaceous only) and water table depth (natural and lowered) treatments to test the effects of plants and water depth on CO2 fluxes, decomposition, and older C loss. We used Δ14C and δ13C of ecosystem CO2 respiration, bulk peat, plants, and porewater dissolved inorganic C to construct mixing models partitioning ER among potential sources. We found that the lowered water table treatments were respiring C fixed before the bomb spike (1955) from deep waterlogged peat. Lowered water table Sedge treatments had the oldest dissolved inorganic 14C signature and the highest proportional peat contribution to ER. Decomposition assays corroborated sustained high rates of decomposition with lowered water tables down to 40 cm below the peat surface. Heterotrophic respiration exceeded plant respiration at the height of the growing season in lowered water table treatments. Rates of gross primary production were only impacted by vegetation, whereas ER was affected by vegetation and water table depth treatments. The decoupling of respiration and primary production with lowered water tables combined with older C losses suggests that climate and land‐use‐induced changes in peatland hydrology can increase the vulnerability of peatland C stores. The combined effects of water table variation and plant community changes on the loss of older carbon in peatlands is currently unknown. We found that lowered water tables induced the loss of older (before 1950) carbon in both sedge and ericaceous plant dominated plots, with the oldest carbon lost in sedge dominated plots. We also saw higher decomposition rates below 10 cm in the peat and a decoupling of gross primary productivity and ecosystem respiration rates with lowered water tables.
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M.</au><au>Tucker, Colin L.</au><au>Lilleskov, Erik A.</au><au>Kolka, Randall K.</au><au>Chimner, Rodney A.</au><au>Heckman, Katherine A.</au><au>Kane, Evan S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Evidence for older carbon loss with lowered water tables and changing plant functional groups in peatlands</atitle><jtitle>Global change biology</jtitle><addtitle>Glob Chang Biol</addtitle><date>2023-02</date><risdate>2023</risdate><volume>29</volume><issue>3</issue><spage>780</spage><epage>793</epage><pages>780-793</pages><issn>1354-1013</issn><eissn>1365-2486</eissn><abstract>A small imbalance in plant productivity and decomposition accounts for the carbon (C) accumulation capacity of peatlands. As climate changes, the continuity of peatland net C storage relies on rising primary production to offset increasing ecosystem respiration (ER) along with the persistence of older C in waterlogged peat. A lowering in the water table position in peatlands often increases decomposition rates, but concurrent plant community shifts can interactively alter ER and plant productivity responses. The combined effects of water table variation and plant communities on older peat C loss are unknown. We used a full‐factorial 1‐m3 mesocosm array with vascular plant functional group manipulations (Unmanipulated Control, Sedge only, and Ericaceous only) and water table depth (natural and lowered) treatments to test the effects of plants and water depth on CO2 fluxes, decomposition, and older C loss. We used Δ14C and δ13C of ecosystem CO2 respiration, bulk peat, plants, and porewater dissolved inorganic C to construct mixing models partitioning ER among potential sources. We found that the lowered water table treatments were respiring C fixed before the bomb spike (1955) from deep waterlogged peat. Lowered water table Sedge treatments had the oldest dissolved inorganic 14C signature and the highest proportional peat contribution to ER. Decomposition assays corroborated sustained high rates of decomposition with lowered water tables down to 40 cm below the peat surface. Heterotrophic respiration exceeded plant respiration at the height of the growing season in lowered water table treatments. Rates of gross primary production were only impacted by vegetation, whereas ER was affected by vegetation and water table depth treatments. The decoupling of respiration and primary production with lowered water tables combined with older C losses suggests that climate and land‐use‐induced changes in peatland hydrology can increase the vulnerability of peatland C stores. The combined effects of water table variation and plant community changes on the loss of older carbon in peatlands is currently unknown. We found that lowered water tables induced the loss of older (before 1950) carbon in both sedge and ericaceous plant dominated plots, with the oldest carbon lost in sedge dominated plots. We also saw higher decomposition rates below 10 cm in the peat and a decoupling of gross primary productivity and ecosystem respiration rates with lowered water tables.</abstract><cop>England</cop><pub>Blackwell Publishing Ltd</pub><pmid>36308039</pmid><doi>10.1111/gcb.16508</doi><tpages>14</tpages><orcidid>https://orcid.org/0000-0002-9208-1631</orcidid><orcidid>https://orcid.org/0000-0003-2265-4542</orcidid><orcidid>https://orcid.org/0000-0003-1665-0596</orcidid><orcidid>https://orcid.org/0000-0002-9238-9513</orcidid><orcidid>https://orcid.org/0000-0001-6515-851X</orcidid><orcidid>https://orcid.org/0000-0003-2679-5211</orcidid><orcidid>https://orcid.org/0000-0002-6419-8218</orcidid><oa>free_for_read</oa></addata></record>
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source MEDLINE; Wiley Online Library Journals Frontfile Complete
subjects Carbon
Carbon dioxide
Carbon Dioxide - analysis
carbon fluxes
Climate change
Decomposition
Decoupling
Ecosystem
ecosystem respiration
Functional groups
Groundwater
Groundwater table
Growing season
histosol
Hydrology
Land use
Mesocosms
mixing models
Peat
Peatlands
Plant communities
Plants
Pore water
Primary production
Productivity
radiocarbon
Respiration
Soil
Storage
Vegetation
Vulnerability
Water depth
Water table
Water table depth
title Evidence for older carbon loss with lowered water tables and changing plant functional groups in peatlands
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