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Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology

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Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology. / Sykes, A.J.; MacLeod, Michael; Eory, V. et al.
In: Global Change Biology, Vol. 26, No. 3, 31.03.2020, p. 1085–1108.

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Harvard

Sykes, AJ, MacLeod, M, Eory, V, Rees, RM, Payen, F, Myrgiotis, V, Williams, M, Sohi, S, Hillier, J, Moran, D, Manning, DAC, Goglio, P, Seghetta, M, Williams, A, Harris, J, Dondini, M, Walton, J, House, J & Smith, P 2020, 'Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology', Global Change Biology, vol. 26, no. 3, pp. 1085–1108. https://doi.org/10.1111/gcb.14844

APA

Sykes, A. J., MacLeod, M., Eory, V., Rees, R. M., Payen, F., Myrgiotis, V., Williams, M., Sohi, S., Hillier, J., Moran, D., Manning, D. A. C., Goglio, P., Seghetta, M., Williams, A., Harris, J., Dondini, M., Walton, J., House, J., & Smith, P. (2020). Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology. Global Change Biology, 26(3), 1085–1108. https://doi.org/10.1111/gcb.14844

Vancouver

Sykes AJ, MacLeod M, Eory V, Rees RM, Payen F, Myrgiotis V et al. Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology. Global Change Biology. 2020 Mar 31;26(3):1085–1108. Epub 2019 Oct 26. doi: 10.1111/gcb.14844

Author

Sykes, A.J. ; MacLeod, Michael ; Eory, V. et al. / Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology. In: Global Change Biology. 2020 ; Vol. 26, No. 3. pp. 1085–1108.

Bibtex

@article{b69ecc8d93684894861db817d358bc7e,
title = "Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology",
abstract = "To limit warming to well below 2°C, most scenario projections rely on greenhouse gas removal technologies (GGRTs); one such GGRT uses soil carbon sequestration (SCS) in agricultural land. In addition to their role in mitigating climate change, SCS practices play a role in delivering agroecosystem resilience, climate change adaptability and food security. Environmental heterogeneity and differences in agricultural practices challenge the practical implementation of SCS, and our analysis addresses the associated knowledge gap. Previous assessments have focused on global potentials, but there is a need among policymakers to operationalise SCS. Here, we assess a range of practices already proposed to deliver SCS, and distil these into a subset of specific measures. We provide a multidisciplinary summary of the barriers and potential incentives towards practical implementation of these measures. First, we identify specific practices with potential for both a positive impact on SCS at farm level and an uptake rate compatible with global impact. These focus on: (a) optimising crop primary productivity (e.g. nutrient optimisation, pH management, irrigation); (b) reducing soil disturbance and managing soil physical properties (e.g. improved rotations, minimum till); (c) minimising deliberate removal of C or lateral transport via erosion processes (e.g. support measures, bare fallow reduction); (d) addition of C produced outside the system (e.g. organic manure amendments, biochar addition); (e) provision of additional C inputs within the cropping system (e.g. agroforestry, cover cropping). We then consider economic and non‐cost barriers and incentives for land managers implementing these measures, along with the potential externalised impacts of implementation. This offers a framework and reference point for holistic assessment of the impacts of SCS. Finally, we summarise and discuss the ability of extant scientific approaches to quantify the technical potential and externalities of SCS measures, and the barriers and incentives to their implementation in global agricultural systems.",
keywords = "4 per mille, agriculture, greenhouse gas removal, negative emissions, soil carbon sequestration, soil organic carbon",
author = "A.J. Sykes and Michael MacLeod and V. Eory and R.M. Rees and F. Payen and V. Myrgiotis and M. Williams and S. Sohi and Jon Hillier and Dominic Moran and D.A.C. Manning and P. Goglio and M. Seghetta and A. Williams and J. Harris and Marta Dondini and J. Walton and J. House and P. Smith",
year = "2020",
month = mar,
day = "31",
doi = "10.1111/gcb.14844",
language = "English",
volume = "26",
pages = "1085–1108",
journal = "Global Change Biology",
issn = "1354-1013",
publisher = "Blackwell Publishing Ltd",
number = "3",

}

RIS

TY - JOUR

T1 - Characterising the biophysical, economic and social impacts of soil carbon sequestration as a greenhouse gas removal technology

AU - Sykes, A.J.

AU - MacLeod, Michael

AU - Eory, V.

AU - Rees, R.M.

AU - Payen, F.

AU - Myrgiotis, V.

AU - Williams, M.

AU - Sohi, S.

AU - Hillier, Jon

AU - Moran, Dominic

AU - Manning, D.A.C.

AU - Goglio, P.

AU - Seghetta, M.

AU - Williams, A.

AU - Harris, J.

AU - Dondini, Marta

AU - Walton, J.

AU - House, J.

AU - Smith, P.

PY - 2020/3/31

Y1 - 2020/3/31

N2 - To limit warming to well below 2°C, most scenario projections rely on greenhouse gas removal technologies (GGRTs); one such GGRT uses soil carbon sequestration (SCS) in agricultural land. In addition to their role in mitigating climate change, SCS practices play a role in delivering agroecosystem resilience, climate change adaptability and food security. Environmental heterogeneity and differences in agricultural practices challenge the practical implementation of SCS, and our analysis addresses the associated knowledge gap. Previous assessments have focused on global potentials, but there is a need among policymakers to operationalise SCS. Here, we assess a range of practices already proposed to deliver SCS, and distil these into a subset of specific measures. We provide a multidisciplinary summary of the barriers and potential incentives towards practical implementation of these measures. First, we identify specific practices with potential for both a positive impact on SCS at farm level and an uptake rate compatible with global impact. These focus on: (a) optimising crop primary productivity (e.g. nutrient optimisation, pH management, irrigation); (b) reducing soil disturbance and managing soil physical properties (e.g. improved rotations, minimum till); (c) minimising deliberate removal of C or lateral transport via erosion processes (e.g. support measures, bare fallow reduction); (d) addition of C produced outside the system (e.g. organic manure amendments, biochar addition); (e) provision of additional C inputs within the cropping system (e.g. agroforestry, cover cropping). We then consider economic and non‐cost barriers and incentives for land managers implementing these measures, along with the potential externalised impacts of implementation. This offers a framework and reference point for holistic assessment of the impacts of SCS. Finally, we summarise and discuss the ability of extant scientific approaches to quantify the technical potential and externalities of SCS measures, and the barriers and incentives to their implementation in global agricultural systems.

AB - To limit warming to well below 2°C, most scenario projections rely on greenhouse gas removal technologies (GGRTs); one such GGRT uses soil carbon sequestration (SCS) in agricultural land. In addition to their role in mitigating climate change, SCS practices play a role in delivering agroecosystem resilience, climate change adaptability and food security. Environmental heterogeneity and differences in agricultural practices challenge the practical implementation of SCS, and our analysis addresses the associated knowledge gap. Previous assessments have focused on global potentials, but there is a need among policymakers to operationalise SCS. Here, we assess a range of practices already proposed to deliver SCS, and distil these into a subset of specific measures. We provide a multidisciplinary summary of the barriers and potential incentives towards practical implementation of these measures. First, we identify specific practices with potential for both a positive impact on SCS at farm level and an uptake rate compatible with global impact. These focus on: (a) optimising crop primary productivity (e.g. nutrient optimisation, pH management, irrigation); (b) reducing soil disturbance and managing soil physical properties (e.g. improved rotations, minimum till); (c) minimising deliberate removal of C or lateral transport via erosion processes (e.g. support measures, bare fallow reduction); (d) addition of C produced outside the system (e.g. organic manure amendments, biochar addition); (e) provision of additional C inputs within the cropping system (e.g. agroforestry, cover cropping). We then consider economic and non‐cost barriers and incentives for land managers implementing these measures, along with the potential externalised impacts of implementation. This offers a framework and reference point for holistic assessment of the impacts of SCS. Finally, we summarise and discuss the ability of extant scientific approaches to quantify the technical potential and externalities of SCS measures, and the barriers and incentives to their implementation in global agricultural systems.

KW - 4 per mille

KW - agriculture

KW - greenhouse gas removal

KW - negative emissions

KW - soil carbon sequestration

KW - soil organic carbon

U2 - 10.1111/gcb.14844

DO - 10.1111/gcb.14844

M3 - Journal article

VL - 26

SP - 1085

EP - 1108

JO - Global Change Biology

JF - Global Change Biology

SN - 1354-1013

IS - 3

ER -