The role of soil carbon in natural climate solutions

A. D. Bossio; S C Cook-Patton; P W  Ellis; J Fargione; J Sanderman; P Smith; S Wood; R J Zomer; M von Unger; I. M. Emmer; B W  Griscrom

doi:10.1038/s41893-020-0491-z

The role of soil carbon in natural climate solutions

A. D. Bossio^* (Corresponding Author), S C Cook-Patton, P W Ellis, J Fargione, J Sanderman, P Smith, S Wood, R J Zomer, M von Unger, I. M. Emmer, B W Griscrom

^*Corresponding author for this work

Aberdeen Centre For Environmental Sustainability

Research output: Contribution to journal › Article › peer-review

240 Citations (Scopus)

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Abstract

Mitigating climate change requires clean energy and the removal of atmospheric carbon. Building soil carbon is an appealing way to increase carbon sinks and reduce emissions owing to the associated benefits to agriculture. However, the practical implementation of soil carbon climate strategies lags behind the potential, partly because we lack clarity around the magnitude of opportunity and how to capitalize on it. Here we quantify the role of soil carbon in natural (land-based) climate solutions and review some of the project design mechanisms available to tap into the potential. We show that soil carbon represents 25% of the potential of natural climate solutions (total potential, 23.8 Gt of CO2-equivalent per year), of which 40% is protection of existing soil carbon and 60% is rebuilding depleted stocks. Soil carbon comprises 9% of the mitigation potential of forests, 72% for wetlands and 47% for agriculture and grasslands. Soil carbon is important to land-based efforts to prevent carbon emissions, remove atmospheric carbon dioxide and deliver ecosystem services in addition to climate mitigation.

Diverse strategies are needed to mitigate climate change. This study finds that storing carbon in soils represents 25% of land-based potential, of which 60% must come from rebuilding depleted carbon stores.

Original language	English
Pages (from-to)	391-398
Number of pages	8
Journal	Nature Sustainability
Volume	3
Early online date	16 Mar 2020
DOIs	https://doi.org/10.1038/s41893-020-0491-z
Publication status	Published - May 2020

Keywords

Agriculture
Climate sciences
Ecology
Environmental sciences
Environmental social sciences
GREENHOUSE-GAS EMISSIONS
MANAGEMENT
AGRICULTURE
ORGANIC-MATTER
OPPORTUNITIES
SEQUESTRATION
PRODUCTIVITY
MITIGATION
DYNAMICS
STOCKS

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1038/s41893-020-0491-zLicence: Unspecified

Bossio_etal_Soil_NCS_AAMAccepted author manuscript, 633 KBLicence: Other

https://zenodo.org/record/883444Licence: CC BY

Cite this

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title = "The role of soil carbon in natural climate solutions",

abstract = "Mitigating climate change requires clean energy and the removal of atmospheric carbon. Building soil carbon is an appealing way to increase carbon sinks and reduce emissions owing to the associated benefits to agriculture. However, the practical implementation of soil carbon climate strategies lags behind the potential, partly because we lack clarity around the magnitude of opportunity and how to capitalize on it. Here we quantify the role of soil carbon in natural (land-based) climate solutions and review some of the project design mechanisms available to tap into the potential. We show that soil carbon represents 25% of the potential of natural climate solutions (total potential, 23.8 Gt of CO2-equivalent per year), of which 40% is protection of existing soil carbon and 60% is rebuilding depleted stocks. Soil carbon comprises 9% of the mitigation potential of forests, 72% for wetlands and 47% for agriculture and grasslands. Soil carbon is important to land-based efforts to prevent carbon emissions, remove atmospheric carbon dioxide and deliver ecosystem services in addition to climate mitigation.Diverse strategies are needed to mitigate climate change. This study finds that storing carbon in soils represents 25% of land-based potential, of which 60% must come from rebuilding depleted carbon stores.",

keywords = "Agriculture, Climate sciences, Ecology, Environmental sciences, Environmental social sciences, GREENHOUSE-GAS EMISSIONS, MANAGEMENT, AGRICULTURE, ORGANIC-MATTER, OPPORTUNITIES, SEQUESTRATION, PRODUCTIVITY, MITIGATION, DYNAMICS, STOCKS",

author = "Bossio, {A. D.} and Cook-Patton, {S C} and Ellis, {P W} and J Fargione and J Sanderman and P Smith and S Wood and Zomer, {R J} and {von Unger}, M and Emmer, {I. M.} and Griscrom, {B W}",

note = "Acknowledgements. This study was made possible by funding from the Craig and Susan McCaw Foundation. Data Deposition A global spatial dataset of reforestation opportunities is available on Zenodo (https://zenodo.org/record/883444). Figures 1 and 2 have associated raw data that can be made available upon request.",

year = "2020",

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doi = "10.1038/s41893-020-0491-z",

language = "English",

volume = "3",

pages = "391--398",

journal = "Nature Sustainability",

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AU - Bossio, A. D.

AU - Cook-Patton, S C

AU - Ellis, P W

AU - Fargione, J

AU - Sanderman, J

AU - Smith, P

AU - Wood, S

AU - Zomer, R J

AU - von Unger, M

AU - Emmer, I. M.

AU - Griscrom, B W

N1 - Acknowledgements. This study was made possible by funding from the Craig and Susan McCaw Foundation. Data Deposition A global spatial dataset of reforestation opportunities is available on Zenodo (https://zenodo.org/record/883444). Figures 1 and 2 have associated raw data that can be made available upon request.

PY - 2020/5

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N2 - Mitigating climate change requires clean energy and the removal of atmospheric carbon. Building soil carbon is an appealing way to increase carbon sinks and reduce emissions owing to the associated benefits to agriculture. However, the practical implementation of soil carbon climate strategies lags behind the potential, partly because we lack clarity around the magnitude of opportunity and how to capitalize on it. Here we quantify the role of soil carbon in natural (land-based) climate solutions and review some of the project design mechanisms available to tap into the potential. We show that soil carbon represents 25% of the potential of natural climate solutions (total potential, 23.8 Gt of CO2-equivalent per year), of which 40% is protection of existing soil carbon and 60% is rebuilding depleted stocks. Soil carbon comprises 9% of the mitigation potential of forests, 72% for wetlands and 47% for agriculture and grasslands. Soil carbon is important to land-based efforts to prevent carbon emissions, remove atmospheric carbon dioxide and deliver ecosystem services in addition to climate mitigation.Diverse strategies are needed to mitigate climate change. This study finds that storing carbon in soils represents 25% of land-based potential, of which 60% must come from rebuilding depleted carbon stores.

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KW - Agriculture

KW - Climate sciences

KW - Ecology

KW - Environmental sciences

KW - Environmental social sciences

KW - GREENHOUSE-GAS EMISSIONS

KW - MANAGEMENT

KW - AGRICULTURE

KW - ORGANIC-MATTER

KW - OPPORTUNITIES

KW - SEQUESTRATION

KW - PRODUCTIVITY

KW - MITIGATION

KW - DYNAMICS

KW - STOCKS

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DO - 10.1038/s41893-020-0491-z

M3 - Article

VL - 3

SP - 391

EP - 398

JO - Nature Sustainability

JF - Nature Sustainability

SN - 2398-9629

ER -

The role of soil carbon in natural climate solutions

Abstract

Keywords

UN SDGs

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Pete Smith

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The role of soil carbon in natural climate solutions

Abstract

Keywords

UN SDGs

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Pete Smith

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