Overriding water table control on managed peatland greenhouse gas emissions

C. D. Evans; M. Peacock; A. J. Baird; R. R.E. Artz; A. Burden; N. Callaghan; P. J. Chapman; H. M. Cooper; M. Coyle; E. Craig; A. Cumming; S. Dixon; V. Gauci; R. P. Grayson; C. Helfter; C. M. Heppell; J. Holden; D. L. Jones; J. Kaduk; P. Levy; R. Matthews; N. P. McNamara; T. Misselbrook; S. Oakley; S. E. Page; M. Rayment; L. M. Ridley; K. M. Stanley; J. L. Williamson; F. Worrall; R. Morrison

doi:10.1038/s41586-021-03523-1

Overriding water table control on managed peatland greenhouse gas emissions

C. D. Evans^*, M. Peacock, A. J. Baird, R. R.E. Artz, A. Burden, N. Callaghan, P. J. Chapman, H. M. Cooper, M. Coyle, E. Craig, A. Cumming, S. Dixon, V. Gauci, R. P. Grayson, C. Helfter, C. M. Heppell, J. Holden, D. L. Jones, J. Kaduk, P. LevyR. Matthews, N. P. McNamara, T. Misselbrook, S. Oakley, S. E. Page, M. Rayment, L. M. Ridley, K. M. Stanley, J. L. Williamson, F. Worrall, R. Morrison

^*Corresponding author for this work

Geography, Earth and Environmental Sciences

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Abstract

Global peatlands store more carbon than is naturally present in the atmosphere^1,2. However, many peatlands are under pressure from drainage-based agriculture, plantation development and fire, with the equivalent of around 3 per cent of all anthropogenic greenhouse gases emitted from drained peatland^3–5. Efforts to curb such emissions are intensifying through the conservation of undrained peatlands and re-wetting of drained systems⁶. Here we report eddy covariance data for carbon dioxide from 16 locations and static chamber measurements for methane from 41 locations in the UK and Ireland. We combine these with published data from sites across all major peatland biomes. We find that the mean annual effective water table depth (WTD_e; that is, the average depth of the aerated peat layer) overrides all other ecosystem- and management-related controls on greenhouse gas fluxes. We estimate that every 10 centimetres of reduction in WTD_e could reduce the net warming impact of CO₂ and CH₄ emissions (100-year global warming potentials) by the equivalent of at least 3 tonnes of CO₂ per hectare per year, until WTD_e is less than 30 centimetres. Raising water levels further would continue to have a net cooling effect until WTD_e is within 10 centimetres of the surface. Our results suggest that greenhouse gas emissions from peatlands drained for agriculture could be greatly reduced without necessarily halting their productive use. Halving WTD_e in all drained agricultural peatlands, for example, could reduce emissions by the equivalent of over 1 per cent of global anthropogenic emissions.

Original language	English
Pages (from-to)	548-552
Number of pages	5
Journal	Nature
Volume	593
Issue number	7860
Early online date	21 Apr 2021
DOIs	https://doi.org/10.1038/s41586-021-03523-1
Publication status	Published - 27 May 2021

Bibliographical note

Funding Information:
Acknowledgements This study was supported by the UK Department for Environment, Food and Rural Affairs (projects SP1210 and SP1218), with additional data provided from projects funded by the UK Natural Environment Research Council (SEFLOS, NE/P0140971/1 and UKSCAPE, NE/R016429/1), Scottish Government and Natural Resources Wales (NRW). UK flux sites were hosted by a range of organizations including G’s Fresh, the National Trust, NRW and the Balmoral Estate. We thank all those responsible for collecting the published data used in the study, in particular M. Strack, D. Holl, H. Keck and C. Deshmukh for providing additional data and information on individual studies, L. Menichetti for sharing peat mapping data and L. Barber at the University of Leicester for preparing the site maps.

Publisher Copyright:
© 2021, The Author(s), under exclusive licence to Springer Nature Limited.

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Evans, C. D., Peacock, M., Baird, A. J., Artz, R. R. E., Burden, A., Callaghan, N., Chapman, P. J., Cooper, H. M., Coyle, M., Craig, E., Cumming, A., Dixon, S., Gauci, V., Grayson, R. P., Helfter, C., Heppell, C. M., Holden, J., Jones, D. L., Kaduk, J., ... Morrison, R. (2021). Overriding water table control on managed peatland greenhouse gas emissions. Nature, 593(7860), 548-552. https://doi.org/10.1038/s41586-021-03523-1

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title = "Overriding water table control on managed peatland greenhouse gas emissions",

abstract = "Global peatlands store more carbon than is naturally present in the atmosphere1,2. However, many peatlands are under pressure from drainage-based agriculture, plantation development and fire, with the equivalent of around 3 per cent of all anthropogenic greenhouse gases emitted from drained peatland3–5. Efforts to curb such emissions are intensifying through the conservation of undrained peatlands and re-wetting of drained systems6. Here we report eddy covariance data for carbon dioxide from 16 locations and static chamber measurements for methane from 41 locations in the UK and Ireland. We combine these with published data from sites across all major peatland biomes. We find that the mean annual effective water table depth (WTDe; that is, the average depth of the aerated peat layer) overrides all other ecosystem- and management-related controls on greenhouse gas fluxes. We estimate that every 10 centimetres of reduction in WTDe could reduce the net warming impact of CO2 and CH4 emissions (100-year global warming potentials) by the equivalent of at least 3 tonnes of CO2 per hectare per year, until WTDe is less than 30 centimetres. Raising water levels further would continue to have a net cooling effect until WTDe is within 10 centimetres of the surface. Our results suggest that greenhouse gas emissions from peatlands drained for agriculture could be greatly reduced without necessarily halting their productive use. Halving WTDe in all drained agricultural peatlands, for example, could reduce emissions by the equivalent of over 1 per cent of global anthropogenic emissions.",

author = "Evans, {C. D.} and M. Peacock and Baird, {A. J.} and Artz, {R. R.E.} and A. Burden and N. Callaghan and Chapman, {P. J.} and Cooper, {H. M.} and M. Coyle and E. Craig and A. Cumming and S. Dixon and V. Gauci and Grayson, {R. P.} and C. Helfter and Heppell, {C. M.} and J. Holden and Jones, {D. L.} and J. Kaduk and P. Levy and R. Matthews and McNamara, {N. P.} and T. Misselbrook and S. Oakley and Page, {S. E.} and M. Rayment and Ridley, {L. M.} and Stanley, {K. M.} and Williamson, {J. L.} and F. Worrall and R. Morrison",

note = "Funding Information: Acknowledgements This study was supported by the UK Department for Environment, Food and Rural Affairs (projects SP1210 and SP1218), with additional data provided from projects funded by the UK Natural Environment Research Council (SEFLOS, NE/P0140971/1 and UKSCAPE, NE/R016429/1), Scottish Government and Natural Resources Wales (NRW). UK flux sites were hosted by a range of organizations including G{\textquoteright}s Fresh, the National Trust, NRW and the Balmoral Estate. We thank all those responsible for collecting the published data used in the study, in particular M. Strack, D. Holl, H. Keck and C. Deshmukh for providing additional data and information on individual studies, L. Menichetti for sharing peat mapping data and L. Barber at the University of Leicester for preparing the site maps. Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Nature Limited.",

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doi = "10.1038/s41586-021-03523-1",

language = "English",

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Evans, CD, Peacock, M, Baird, AJ, Artz, RRE, Burden, A, Callaghan, N, Chapman, PJ, Cooper, HM, Coyle, M, Craig, E, Cumming, A, Dixon, S, Gauci, V, Grayson, RP, Helfter, C, Heppell, CM, Holden, J, Jones, DL, Kaduk, J, Levy, P, Matthews, R, McNamara, NP, Misselbrook, T, Oakley, S, Page, SE, Rayment, M, Ridley, LM, Stanley, KM, Williamson, JL, Worrall, F & Morrison, R 2021, 'Overriding water table control on managed peatland greenhouse gas emissions', Nature, vol. 593, no. 7860, pp. 548-552. https://doi.org/10.1038/s41586-021-03523-1

TY - JOUR

T1 - Overriding water table control on managed peatland greenhouse gas emissions

AU - Evans, C. D.

AU - Peacock, M.

AU - Baird, A. J.

AU - Artz, R. R.E.

AU - Burden, A.

AU - Callaghan, N.

AU - Chapman, P. J.

AU - Cooper, H. M.

AU - Coyle, M.

AU - Craig, E.

AU - Cumming, A.

AU - Dixon, S.

AU - Gauci, V.

AU - Grayson, R. P.

AU - Helfter, C.

AU - Heppell, C. M.

AU - Holden, J.

AU - Jones, D. L.

AU - Kaduk, J.

AU - Levy, P.

AU - Matthews, R.

AU - McNamara, N. P.

AU - Misselbrook, T.

AU - Oakley, S.

AU - Page, S. E.

AU - Rayment, M.

AU - Ridley, L. M.

AU - Stanley, K. M.

AU - Williamson, J. L.

AU - Worrall, F.

AU - Morrison, R.

N1 - Funding Information: Acknowledgements This study was supported by the UK Department for Environment, Food and Rural Affairs (projects SP1210 and SP1218), with additional data provided from projects funded by the UK Natural Environment Research Council (SEFLOS, NE/P0140971/1 and UKSCAPE, NE/R016429/1), Scottish Government and Natural Resources Wales (NRW). UK flux sites were hosted by a range of organizations including G’s Fresh, the National Trust, NRW and the Balmoral Estate. We thank all those responsible for collecting the published data used in the study, in particular M. Strack, D. Holl, H. Keck and C. Deshmukh for providing additional data and information on individual studies, L. Menichetti for sharing peat mapping data and L. Barber at the University of Leicester for preparing the site maps. Publisher Copyright: © 2021, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2021/5/27

Y1 - 2021/5/27

N2 - Global peatlands store more carbon than is naturally present in the atmosphere1,2. However, many peatlands are under pressure from drainage-based agriculture, plantation development and fire, with the equivalent of around 3 per cent of all anthropogenic greenhouse gases emitted from drained peatland3–5. Efforts to curb such emissions are intensifying through the conservation of undrained peatlands and re-wetting of drained systems6. Here we report eddy covariance data for carbon dioxide from 16 locations and static chamber measurements for methane from 41 locations in the UK and Ireland. We combine these with published data from sites across all major peatland biomes. We find that the mean annual effective water table depth (WTDe; that is, the average depth of the aerated peat layer) overrides all other ecosystem- and management-related controls on greenhouse gas fluxes. We estimate that every 10 centimetres of reduction in WTDe could reduce the net warming impact of CO2 and CH4 emissions (100-year global warming potentials) by the equivalent of at least 3 tonnes of CO2 per hectare per year, until WTDe is less than 30 centimetres. Raising water levels further would continue to have a net cooling effect until WTDe is within 10 centimetres of the surface. Our results suggest that greenhouse gas emissions from peatlands drained for agriculture could be greatly reduced without necessarily halting their productive use. Halving WTDe in all drained agricultural peatlands, for example, could reduce emissions by the equivalent of over 1 per cent of global anthropogenic emissions.

AB - Global peatlands store more carbon than is naturally present in the atmosphere1,2. However, many peatlands are under pressure from drainage-based agriculture, plantation development and fire, with the equivalent of around 3 per cent of all anthropogenic greenhouse gases emitted from drained peatland3–5. Efforts to curb such emissions are intensifying through the conservation of undrained peatlands and re-wetting of drained systems6. Here we report eddy covariance data for carbon dioxide from 16 locations and static chamber measurements for methane from 41 locations in the UK and Ireland. We combine these with published data from sites across all major peatland biomes. We find that the mean annual effective water table depth (WTDe; that is, the average depth of the aerated peat layer) overrides all other ecosystem- and management-related controls on greenhouse gas fluxes. We estimate that every 10 centimetres of reduction in WTDe could reduce the net warming impact of CO2 and CH4 emissions (100-year global warming potentials) by the equivalent of at least 3 tonnes of CO2 per hectare per year, until WTDe is less than 30 centimetres. Raising water levels further would continue to have a net cooling effect until WTDe is within 10 centimetres of the surface. Our results suggest that greenhouse gas emissions from peatlands drained for agriculture could be greatly reduced without necessarily halting their productive use. Halving WTDe in all drained agricultural peatlands, for example, could reduce emissions by the equivalent of over 1 per cent of global anthropogenic emissions.

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JO - Nature

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ER -

Overriding water table control on managed peatland greenhouse gas emissions

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