Transforming US agriculture for carbon removal with enhanced weathering

David J. Beerling; Euripides P. Kantzas; Mark R. Lomas; Lyla L. Taylor; Shuang Zhang; Yoshiki Kanzaki; Rafael M. Eufrasio; Phil Renforth; Jean-Francois Mecure; Hector Pollitt; Philip B. Holden; Neil R. Edwards; Lenny Koh; Dimitar Z. Epihov; Adam Wolf; James E. Hansen; Steven A. Banwart; Nick F. Pidgeon; Christopher T. Reinhard; Noah J. Planavsky; Maria Val Martin

doi:10.1038/s41586-024-08429-2

Transforming US agriculture for carbon removal with enhanced weathering

David J. Beerling^*, Euripides P. Kantzas, Mark R. Lomas, Lyla L. Taylor, Shuang Zhang, Yoshiki Kanzaki, Rafael M. Eufrasio, Phil Renforth, Jean-Francois Mecure, Hector Pollitt, Philip B. Holden, Neil R. Edwards, Lenny Koh, Dimitar Z. Epihov, Adam Wolf, James E. Hansen, Steven A. Banwart, Nick F. Pidgeon, Christopher T. Reinhard, Noah J. PlanavskyMaria Val Martin

^*Corresponding author for this work

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

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Abstract

Enhanced weathering (EW) with agriculture uses crushed silicate rocks to drive carbon dioxide removal (CDR)1, 2. If widely adopted on farmlands, it could help achieve net-zero emissions by 20502, 3–4. Here we show, with a detailed US state-specific carbon cycle analysis constrained by resource provision, that EW deployed on agricultural land could sequester 0.16–0.30 GtCO2 yr−1 by 2050, rising to 0.25–0.49 GtCO2 yr−1 by 2070. Geochemical assessment of rivers and oceans suggests effective transport of dissolved products from EW from soils, offering CDR on intergenerational timescales. Our analysis further indicates that EW may temporarily help lower ground-level ozone and concentrations of secondary aerosols in agricultural regions. Geospatially mapped CDR costs show heterogeneity across the USA, reflecting a combination of cropland distance from basalt source regions, timing of EW deployment and evolving CDR rates. CDR costs are highest in the first two decades before declining to about US$100–150 tCO2−1 by 2050, including for states that contribute most to total national CDR. Although EW cannot be a substitute for emission reductions, our assessment strengthens the case for EW as an overlooked practical innovation for helping the USA meet net-zero 2050 goals5, 6. Public awareness of EW and equity impacts of EW deployment across the USA require further exploration7, 8 and we note that mobilizing an EW industry at the necessary scale could take decades.

Original language	English
Pages (from-to)	425-434
Number of pages	10
Journal	Nature
Volume	638
Issue number	8050
Early online date	5 Feb 2025
DOIs	https://doi.org/10.1038/s41586-024-08429-2
Publication status	Published - 13 Feb 2025

Keywords

carbon cycle
climate and Earth system modelling

UN SDGs

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

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Beerling, D. J., Kantzas, E. P., Lomas, M. R., Taylor, L. L., Zhang, S., Kanzaki, Y., Eufrasio, R. M., Renforth, P., Mecure, J.-F., Pollitt, H., Holden, P. B., Edwards, N. R., Koh, L., Epihov, D. Z., Wolf, A., Hansen, J. E., Banwart, S. A., Pidgeon, N. F., Reinhard, C. T., ... Val Martin, M. (2025). Transforming US agriculture for carbon removal with enhanced weathering. Nature, 638(8050), 425-434. https://doi.org/10.1038/s41586-024-08429-2

@article{f81edef10def4ef7af47d48eb04448ba,

title = "Transforming US agriculture for carbon removal with enhanced weathering",

abstract = "Enhanced weathering (EW) with agriculture uses crushed silicate rocks to drive carbon dioxide removal (CDR)1, 2. If widely adopted on farmlands, it could help achieve net-zero emissions by 20502, 3–4. Here we show, with a detailed US state-specific carbon cycle analysis constrained by resource provision, that EW deployed on agricultural land could sequester 0.16–0.30 GtCO2 yr−1 by 2050, rising to 0.25–0.49 GtCO2 yr−1 by 2070. Geochemical assessment of rivers and oceans suggests effective transport of dissolved products from EW from soils, offering CDR on intergenerational timescales. Our analysis further indicates that EW may temporarily help lower ground-level ozone and concentrations of secondary aerosols in agricultural regions. Geospatially mapped CDR costs show heterogeneity across the USA, reflecting a combination of cropland distance from basalt source regions, timing of EW deployment and evolving CDR rates. CDR costs are highest in the first two decades before declining to about US$100–150 tCO2−1 by 2050, including for states that contribute most to total national CDR. Although EW cannot be a substitute for emission reductions, our assessment strengthens the case for EW as an overlooked practical innovation for helping the USA meet net-zero 2050 goals5, 6. Public awareness of EW and equity impacts of EW deployment across the USA require further exploration7, 8 and we note that mobilizing an EW industry at the necessary scale could take decades.",

keywords = "carbon cycle, climate and Earth system modelling",

author = "Beerling, {David J.} and Kantzas, {Euripides P.} and Lomas, {Mark R.} and Taylor, {Lyla L.} and Shuang Zhang and Yoshiki Kanzaki and Eufrasio, {Rafael M.} and Phil Renforth and Jean-Francois Mecure and Hector Pollitt and Holden, {Philip B.} and Edwards, {Neil R.} and Lenny Koh and Epihov, {Dimitar Z.} and Adam Wolf and Hansen, {James E.} and Banwart, {Steven A.} and Pidgeon, {Nick F.} and Reinhard, {Christopher T.} and Planavsky, {Noah J.} and {Val Martin}, Maria",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = feb,

day = "13",

doi = "10.1038/s41586-024-08429-2",

language = "English",

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Beerling, DJ, Kantzas, EP, Lomas, MR, Taylor, LL, Zhang, S, Kanzaki, Y, Eufrasio, RM, Renforth, P, Mecure, J-F, Pollitt, H, Holden, PB, Edwards, NR, Koh, L, Epihov, DZ, Wolf, A, Hansen, JE, Banwart, SA, Pidgeon, NF, Reinhard, CT, Planavsky, NJ & Val Martin, M 2025, 'Transforming US agriculture for carbon removal with enhanced weathering', Nature, vol. 638, no. 8050, pp. 425-434. https://doi.org/10.1038/s41586-024-08429-2

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T1 - Transforming US agriculture for carbon removal with enhanced weathering

AU - Beerling, David J.

AU - Kantzas, Euripides P.

AU - Lomas, Mark R.

AU - Taylor, Lyla L.

AU - Zhang, Shuang

AU - Kanzaki, Yoshiki

AU - Eufrasio, Rafael M.

AU - Renforth, Phil

AU - Mecure, Jean-Francois

AU - Pollitt, Hector

AU - Holden, Philip B.

AU - Edwards, Neil R.

AU - Koh, Lenny

AU - Epihov, Dimitar Z.

AU - Wolf, Adam

AU - Hansen, James E.

AU - Banwart, Steven A.

AU - Pidgeon, Nick F.

AU - Reinhard, Christopher T.

AU - Planavsky, Noah J.

AU - Val Martin, Maria

PY - 2025/2/13

Y1 - 2025/2/13

N2 - Enhanced weathering (EW) with agriculture uses crushed silicate rocks to drive carbon dioxide removal (CDR)1, 2. If widely adopted on farmlands, it could help achieve net-zero emissions by 20502, 3–4. Here we show, with a detailed US state-specific carbon cycle analysis constrained by resource provision, that EW deployed on agricultural land could sequester 0.16–0.30 GtCO2 yr−1 by 2050, rising to 0.25–0.49 GtCO2 yr−1 by 2070. Geochemical assessment of rivers and oceans suggests effective transport of dissolved products from EW from soils, offering CDR on intergenerational timescales. Our analysis further indicates that EW may temporarily help lower ground-level ozone and concentrations of secondary aerosols in agricultural regions. Geospatially mapped CDR costs show heterogeneity across the USA, reflecting a combination of cropland distance from basalt source regions, timing of EW deployment and evolving CDR rates. CDR costs are highest in the first two decades before declining to about US$100–150 tCO2−1 by 2050, including for states that contribute most to total national CDR. Although EW cannot be a substitute for emission reductions, our assessment strengthens the case for EW as an overlooked practical innovation for helping the USA meet net-zero 2050 goals5, 6. Public awareness of EW and equity impacts of EW deployment across the USA require further exploration7, 8 and we note that mobilizing an EW industry at the necessary scale could take decades.

AB - Enhanced weathering (EW) with agriculture uses crushed silicate rocks to drive carbon dioxide removal (CDR)1, 2. If widely adopted on farmlands, it could help achieve net-zero emissions by 20502, 3–4. Here we show, with a detailed US state-specific carbon cycle analysis constrained by resource provision, that EW deployed on agricultural land could sequester 0.16–0.30 GtCO2 yr−1 by 2050, rising to 0.25–0.49 GtCO2 yr−1 by 2070. Geochemical assessment of rivers and oceans suggests effective transport of dissolved products from EW from soils, offering CDR on intergenerational timescales. Our analysis further indicates that EW may temporarily help lower ground-level ozone and concentrations of secondary aerosols in agricultural regions. Geospatially mapped CDR costs show heterogeneity across the USA, reflecting a combination of cropland distance from basalt source regions, timing of EW deployment and evolving CDR rates. CDR costs are highest in the first two decades before declining to about US$100–150 tCO2−1 by 2050, including for states that contribute most to total national CDR. Although EW cannot be a substitute for emission reductions, our assessment strengthens the case for EW as an overlooked practical innovation for helping the USA meet net-zero 2050 goals5, 6. Public awareness of EW and equity impacts of EW deployment across the USA require further exploration7, 8 and we note that mobilizing an EW industry at the necessary scale could take decades.

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KW - climate and Earth system modelling

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U2 - 10.1038/s41586-024-08429-2

DO - 10.1038/s41586-024-08429-2

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SN - 0028-0836

VL - 638

SP - 425

EP - 434

JO - Nature

JF - Nature

IS - 8050

ER -

Transforming US agriculture for carbon removal with enhanced weathering

Abstract

Keywords

UN SDGs

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