Soil carbon storage capacity of drylands under altered fire regimes

Adam F.A. Pellegrini; Peter B. Reich; Sarah E. Hobbie; Corli Coetsee; Benjamin Wigley; Edmund February; Katerina Georgiou; Cesar Terrer; E. N.J. Brookshire; Anders Ahlström; Lars Nieradzik; Stephen Sitch; Joe R. Melton; Matthew Forrest; Fang Li; Stijn Hantson; Chantelle Burton; Chao Yue; Philippe Ciais; Robert B. Jackson

doi:10.1038/s41558-023-01800-7

Soil carbon storage capacity of drylands under altered fire regimes

Adam F.A. Pellegrini, Peter B. Reich, Sarah E. Hobbie, Corli Coetsee, Benjamin Wigley, Edmund February, Katerina Georgiou, Cesar Terrer, E. N.J. Brookshire, Anders Ahlström, Lars Nieradzik, Stephen Sitch, Joe R. Melton, Matthew Forrest, Fang Li, Stijn Hantson, Chantelle Burton, Chao Yue, Philippe Ciais, Robert B. Jackson

Facultad de Ciencias Naturales

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

Resumen

The determinants of fire-driven changes in soil organic carbon (SOC) across broad environmental gradients remains unclear, especially in global drylands. Here we combined datasets and field sampling of fire-manipulation experiments to evaluate where and why fire changes SOC and compared our statistical model to simulations from ecosystem models. Drier ecosystems experienced larger relative changes in SOC than humid ecosystems—in some cases exceeding losses from plant biomass pools—primarily explained by high fire-driven declines in tree biomass inputs in dry ecosystems. Many ecosystem models underestimated the SOC changes in drier ecosystems. Upscaling our statistical model predicted that soils in savannah–grassland regions may have gained 0.64 PgC due to net-declines in burned area over the past approximately two decades. Consequently, ongoing declines in fire frequencies have probably created an extensive carbon sink in the soils of global drylands that may have been underestimated by ecosystem models.

Idioma original	Inglés estadounidense
Páginas (desde-hasta)	1089-1094
Número de páginas	6
Publicación	Nature Climate Change
Volumen	13
N.º	10
DOI	https://doi.org/10.1038/s41558-023-01800-7
Estado	Publicada - oct. 2023

Áreas temáticas de ASJC Scopus

Ciencias ambientales (miscelánea)
Ciencias sociales (miscelánea)

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10.1038/s41558-023-01800-7

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Pellegrini, A. F. A., Reich, P. B., Hobbie, S. E., Coetsee, C., Wigley, B., February, E., Georgiou, K., Terrer, C., Brookshire, E. N. J., Ahlström, A., Nieradzik, L., Sitch, S., Melton, J. R., Forrest, M., Li, F., Hantson, S., Burton, C., Yue, C., Ciais, P., & Jackson, R. B. (2023). Soil carbon storage capacity of drylands under altered fire regimes. Nature Climate Change, 13(10), 1089-1094. https://doi.org/10.1038/s41558-023-01800-7

@article{46c25858202e45e085b021fc0e50aabb,

title = "Soil carbon storage capacity of drylands under altered fire regimes",

abstract = "The determinants of fire-driven changes in soil organic carbon (SOC) across broad environmental gradients remains unclear, especially in global drylands. Here we combined datasets and field sampling of fire-manipulation experiments to evaluate where and why fire changes SOC and compared our statistical model to simulations from ecosystem models. Drier ecosystems experienced larger relative changes in SOC than humid ecosystems—in some cases exceeding losses from plant biomass pools—primarily explained by high fire-driven declines in tree biomass inputs in dry ecosystems. Many ecosystem models underestimated the SOC changes in drier ecosystems. Upscaling our statistical model predicted that soils in savannah–grassland regions may have gained 0.64 PgC due to net-declines in burned area over the past approximately two decades. Consequently, ongoing declines in fire frequencies have probably created an extensive carbon sink in the soils of global drylands that may have been underestimated by ecosystem models.",

author = "Pellegrini, {Adam F.A.} and Reich, {Peter B.} and Hobbie, {Sarah E.} and Corli Coetsee and Benjamin Wigley and Edmund February and Katerina Georgiou and Cesar Terrer and Brookshire, {E. N.J.} and Anders Ahlstr{\"o}m and Lars Nieradzik and Stephen Sitch and Melton, {Joe R.} and Matthew Forrest and Fang Li and Stijn Hantson and Chantelle Burton and Chao Yue and Philippe Ciais and Jackson, {Robert B.}",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = oct,

doi = "10.1038/s41558-023-01800-7",

language = "English (US)",

volume = "13",

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journal = "Nature Climate Change",

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Pellegrini, AFA, Reich, PB, Hobbie, SE, Coetsee, C, Wigley, B, February, E, Georgiou, K, Terrer, C, Brookshire, ENJ, Ahlström, A, Nieradzik, L, Sitch, S, Melton, JR, Forrest, M, Li, F, Hantson, S, Burton, C, Yue, C, Ciais, P & Jackson, RB 2023, 'Soil carbon storage capacity of drylands under altered fire regimes', Nature Climate Change, vol. 13, n.º 10, pp. 1089-1094. https://doi.org/10.1038/s41558-023-01800-7

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AU - Pellegrini, Adam F.A.

AU - Reich, Peter B.

AU - Hobbie, Sarah E.

AU - Coetsee, Corli

AU - Wigley, Benjamin

AU - February, Edmund

AU - Georgiou, Katerina

AU - Terrer, Cesar

AU - Brookshire, E. N.J.

AU - Ahlström, Anders

AU - Nieradzik, Lars

AU - Sitch, Stephen

AU - Melton, Joe R.

AU - Forrest, Matthew

AU - Li, Fang

AU - Hantson, Stijn

AU - Burton, Chantelle

AU - Yue, Chao

AU - Ciais, Philippe

AU - Jackson, Robert B.

PY - 2023/10

Y1 - 2023/10

N2 - The determinants of fire-driven changes in soil organic carbon (SOC) across broad environmental gradients remains unclear, especially in global drylands. Here we combined datasets and field sampling of fire-manipulation experiments to evaluate where and why fire changes SOC and compared our statistical model to simulations from ecosystem models. Drier ecosystems experienced larger relative changes in SOC than humid ecosystems—in some cases exceeding losses from plant biomass pools—primarily explained by high fire-driven declines in tree biomass inputs in dry ecosystems. Many ecosystem models underestimated the SOC changes in drier ecosystems. Upscaling our statistical model predicted that soils in savannah–grassland regions may have gained 0.64 PgC due to net-declines in burned area over the past approximately two decades. Consequently, ongoing declines in fire frequencies have probably created an extensive carbon sink in the soils of global drylands that may have been underestimated by ecosystem models.

AB - The determinants of fire-driven changes in soil organic carbon (SOC) across broad environmental gradients remains unclear, especially in global drylands. Here we combined datasets and field sampling of fire-manipulation experiments to evaluate where and why fire changes SOC and compared our statistical model to simulations from ecosystem models. Drier ecosystems experienced larger relative changes in SOC than humid ecosystems—in some cases exceeding losses from plant biomass pools—primarily explained by high fire-driven declines in tree biomass inputs in dry ecosystems. Many ecosystem models underestimated the SOC changes in drier ecosystems. Upscaling our statistical model predicted that soils in savannah–grassland regions may have gained 0.64 PgC due to net-declines in burned area over the past approximately two decades. Consequently, ongoing declines in fire frequencies have probably created an extensive carbon sink in the soils of global drylands that may have been underestimated by ecosystem models.

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Soil carbon storage capacity of drylands under altered fire regimes

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