Bomb radiocarbon evidence for strong global carbon uptake and turnover in terrestrial vegetation

Heather D. Graven; Hamish Warren; Holly K. Gibbs; Samar Khatiwala; Charles Koven; Joanna Lester; Ingeborg Levin; Seth A. Spawn-Lee; Will Wieder

doi:10.1126/science.adl4443

Bomb radiocarbon evidence for strong global carbon uptake and turnover in terrestrial vegetation

Heather D. Graven, Hamish Warren, Holly K. Gibbs, Samar Khatiwala, Charles Koven, Joanna Lester, Ingeborg Levin, Seth A. Spawn-Lee, Will Wieder

Terrestrial Sciences

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

8 Scopus citations

Abstract

Vegetation and soils are taking up approximately 30% of anthropogenic carbon dioxide emissions because of small imbalances in large gross carbon exchanges from productivity and turnover that are poorly constrained. We combined a new budget of radiocarbon produced by nuclear bomb testing in the 1960s with model simulations to evaluate carbon cycling in terrestrial vegetation. We found that most state-of-the-art vegetation models used in the Coupled Model Intercomparison Project underestimated the radiocarbon accumulation in vegetation biomass. Our findings, combined with constraints on vegetation carbon stocks and productivity trends, imply that net primary productivity is likely at least 80 petagrams of carbon per year presently, compared with the 43 to 76 petagrams per year predicted by current models. Storage of anthropogenic carbon in terrestrial vegetation is likely more short-lived and vulnerable than previously predicted.

Original language	English
Pages (from-to)	1335-1339
Number of pages	5
Journal	Science
Volume	384
Issue number	6702
DOIs	https://doi.org/10.1126/science.adl4443
State	Published - Jun 21 2024

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title = "Bomb radiocarbon evidence for strong global carbon uptake and turnover in terrestrial vegetation",

abstract = "Vegetation and soils are taking up approximately 30\% of anthropogenic carbon dioxide emissions because of small imbalances in large gross carbon exchanges from productivity and turnover that are poorly constrained. We combined a new budget of radiocarbon produced by nuclear bomb testing in the 1960s with model simulations to evaluate carbon cycling in terrestrial vegetation. We found that most state-of-the-art vegetation models used in the Coupled Model Intercomparison Project underestimated the radiocarbon accumulation in vegetation biomass. Our findings, combined with constraints on vegetation carbon stocks and productivity trends, imply that net primary productivity is likely at least 80 petagrams of carbon per year presently, compared with the 43 to 76 petagrams per year predicted by current models. Storage of anthropogenic carbon in terrestrial vegetation is likely more short-lived and vulnerable than previously predicted.",

author = "Graven, \{Heather D.\} and Hamish Warren and Gibbs, \{Holly K.\} and Samar Khatiwala and Charles Koven and Joanna Lester and Ingeborg Levin and Spawn-Lee, \{Seth A.\} and Will Wieder",

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T1 - Bomb radiocarbon evidence for strong global carbon uptake and turnover in terrestrial vegetation

AU - Graven, Heather D.

AU - Warren, Hamish

AU - Gibbs, Holly K.

AU - Khatiwala, Samar

AU - Koven, Charles

AU - Lester, Joanna

AU - Levin, Ingeborg

AU - Spawn-Lee, Seth A.

AU - Wieder, Will

PY - 2024/6/21

Y1 - 2024/6/21

N2 - Vegetation and soils are taking up approximately 30% of anthropogenic carbon dioxide emissions because of small imbalances in large gross carbon exchanges from productivity and turnover that are poorly constrained. We combined a new budget of radiocarbon produced by nuclear bomb testing in the 1960s with model simulations to evaluate carbon cycling in terrestrial vegetation. We found that most state-of-the-art vegetation models used in the Coupled Model Intercomparison Project underestimated the radiocarbon accumulation in vegetation biomass. Our findings, combined with constraints on vegetation carbon stocks and productivity trends, imply that net primary productivity is likely at least 80 petagrams of carbon per year presently, compared with the 43 to 76 petagrams per year predicted by current models. Storage of anthropogenic carbon in terrestrial vegetation is likely more short-lived and vulnerable than previously predicted.

AB - Vegetation and soils are taking up approximately 30% of anthropogenic carbon dioxide emissions because of small imbalances in large gross carbon exchanges from productivity and turnover that are poorly constrained. We combined a new budget of radiocarbon produced by nuclear bomb testing in the 1960s with model simulations to evaluate carbon cycling in terrestrial vegetation. We found that most state-of-the-art vegetation models used in the Coupled Model Intercomparison Project underestimated the radiocarbon accumulation in vegetation biomass. Our findings, combined with constraints on vegetation carbon stocks and productivity trends, imply that net primary productivity is likely at least 80 petagrams of carbon per year presently, compared with the 43 to 76 petagrams per year predicted by current models. Storage of anthropogenic carbon in terrestrial vegetation is likely more short-lived and vulnerable than previously predicted.

UR - https://www.scopus.com/pages/publications/85196889512

U2 - 10.1126/science.adl4443

DO - 10.1126/science.adl4443

M3 - Article

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AN - SCOPUS:85196889512

SN - 0036-8075

VL - 384

SP - 1335

EP - 1339

JO - Science

JF - Science

IS - 6702

ER -

Bomb radiocarbon evidence for strong global carbon uptake and turnover in terrestrial vegetation

Abstract

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