Ecosystem productivity has a stronger influence than soil age on surface soil carbon storage across global biomes

Cesar Plaza; Pablo García-Palacios; Asmeret Asefaw Berhe; Jesus Barquero; Felipe Bastida; G. Kenny Png; Ana Rey; Richard D. Bardgett; Manuel Delgado-Baquerizo

doi:10.1038/s43247-022-00567-7

Ecosystem productivity has a stronger influence than soil age on surface soil carbon storage across global biomes

Cesar Plaza, Pablo García-Palacios, Asmeret Asefaw Berhe, Jesus Barquero, Felipe Bastida, G. Kenny Png, Ana Rey, Richard D. Bardgett, Manuel Delgado-Baquerizo

Western Sydney University

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

12 Citations (Scopus)

Abstract

Interactions between soil organic matter and minerals largely govern the carbon sequestration capacity of soils. Yet, variations in the proportions of free light (unprotected) and mineral-associated (protected) carbon as soil develops in contrasting ecosystems are poorly constrained. Here, we studied 16 long-term chronosequences from six continents and found that the ecosystem type is more important than soil age (centuries to millennia) in explaining the proportion of unprotected and mineral-associated carbon fractions in surface soils across global biomes. Soil carbon pools in highly productive tropical and temperate forests were dominated by the unprotected carbon fraction and were highly vulnerable to reductions in ecosystem productivity and warming. Conversely, soil carbon in low productivity, drier and colder ecosystems was dominated by mineral-protected carbon, and was less responsive to warming. Our findings emphasize the importance of conserving ecosystem productivity to protect carbon stored in surface soils.

Original language	English
Article number	233
Number of pages	8
Journal	Communications Earth and Environment
Volume	3
Issue number	1
DOIs	https://doi.org/10.1038/s43247-022-00567-7
Publication status	Published - 2022

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abstract = "Interactions between soil organic matter and minerals largely govern the carbon sequestration capacity of soils. Yet, variations in the proportions of free light (unprotected) and mineral-associated (protected) carbon as soil develops in contrasting ecosystems are poorly constrained. Here, we studied 16 long-term chronosequences from six continents and found that the ecosystem type is more important than soil age (centuries to millennia) in explaining the proportion of unprotected and mineral-associated carbon fractions in surface soils across global biomes. Soil carbon pools in highly productive tropical and temperate forests were dominated by the unprotected carbon fraction and were highly vulnerable to reductions in ecosystem productivity and warming. Conversely, soil carbon in low productivity, drier and colder ecosystems was dominated by mineral-protected carbon, and was less responsive to warming. Our findings emphasize the importance of conserving ecosystem productivity to protect carbon stored in surface soils.",

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AU - Plaza, Cesar

AU - García-Palacios, Pablo

AU - Berhe, Asmeret Asefaw

AU - Barquero, Jesus

AU - Bastida, Felipe

AU - Png, G. Kenny

AU - Rey, Ana

AU - Bardgett, Richard D.

AU - Delgado-Baquerizo, Manuel

PY - 2022

Y1 - 2022

N2 - Interactions between soil organic matter and minerals largely govern the carbon sequestration capacity of soils. Yet, variations in the proportions of free light (unprotected) and mineral-associated (protected) carbon as soil develops in contrasting ecosystems are poorly constrained. Here, we studied 16 long-term chronosequences from six continents and found that the ecosystem type is more important than soil age (centuries to millennia) in explaining the proportion of unprotected and mineral-associated carbon fractions in surface soils across global biomes. Soil carbon pools in highly productive tropical and temperate forests were dominated by the unprotected carbon fraction and were highly vulnerable to reductions in ecosystem productivity and warming. Conversely, soil carbon in low productivity, drier and colder ecosystems was dominated by mineral-protected carbon, and was less responsive to warming. Our findings emphasize the importance of conserving ecosystem productivity to protect carbon stored in surface soils.

AB - Interactions between soil organic matter and minerals largely govern the carbon sequestration capacity of soils. Yet, variations in the proportions of free light (unprotected) and mineral-associated (protected) carbon as soil develops in contrasting ecosystems are poorly constrained. Here, we studied 16 long-term chronosequences from six continents and found that the ecosystem type is more important than soil age (centuries to millennia) in explaining the proportion of unprotected and mineral-associated carbon fractions in surface soils across global biomes. Soil carbon pools in highly productive tropical and temperate forests were dominated by the unprotected carbon fraction and were highly vulnerable to reductions in ecosystem productivity and warming. Conversely, soil carbon in low productivity, drier and colder ecosystems was dominated by mineral-protected carbon, and was less responsive to warming. Our findings emphasize the importance of conserving ecosystem productivity to protect carbon stored in surface soils.

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VL - 3

JO - Communications Earth and Environment

JF - Communications Earth and Environment

IS - 1

M1 - 233

ER -

Ecosystem productivity has a stronger influence than soil age on surface soil carbon storage across global biomes

Abstract

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