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Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil

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Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil. / Kelland, Mike E.; Wade, Peter W.; Lewis, Amy L. et al.
In: Global Change Biology, 21.04.2020.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Kelland, ME, Wade, PW, Lewis, AL, Taylor, LL, Sarkar, B, Andrews, MG, Lomas, MR, Cotton, TEA, Kemp, SJ, James, RH, Pearce, CR, Hartley, SE, Hodson, ME, Leake, JR, Banwart, SA & Beerling, DJ 2020, 'Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil', Global Change Biology. https://doi.org/10.1111/gcb.15089

APA

Kelland, M. E., Wade, P. W., Lewis, A. L., Taylor, L. L., Sarkar, B., Andrews, M. G., Lomas, M. R., Cotton, T. E. A., Kemp, S. J., James, R. H., Pearce, C. R., Hartley, S. E., Hodson, M. E., Leake, J. R., Banwart, S. A., & Beerling, D. J. (2020). Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil. Global Change Biology. Advance online publication. https://doi.org/10.1111/gcb.15089

Vancouver

Kelland ME, Wade PW, Lewis AL, Taylor LL, Sarkar B, Andrews MG et al. Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil. Global Change Biology. 2020 Apr 21. Epub 2020 Apr 21. doi: 10.1111/gcb.15089

Author

Kelland, Mike E. ; Wade, Peter W. ; Lewis, Amy L. et al. / Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil. In: Global Change Biology. 2020.

Bibtex

@article{86234ec77c974a028339bd34a6f9b484,
title = "Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil",
abstract = "Land‐based enhanced rock weathering (ERW) is a biogeochemical carbon dioxide removal (CDR) strategy aiming to accelerate natural geological processes of carbon sequestration through application of crushed silicate rocks, such as basalt, to croplands and forested landscapes. However, the efficacy of the approach when undertaken with basalt, and its potential co‐benefits for agriculture, require experimental and field evaluation. Here we report that amending a UK clay‐loam agricultural soil with a high loading (10 kg/m2) of relatively coarse‐grained crushed basalt significantly increased the yield (21 ± 9.4%, SE) of the important C4 cereal Sorghum bicolor under controlled environmental conditions, without accumulation of potentially toxic trace elements in the seeds. Yield increases resulted from the basalt treatment after 120 days without P‐ and K‐fertilizer addition. Shoot silicon concentrations also increased significantly (26 ± 5.4%, SE), with potential benefits for crop resistance to biotic and abiotic stress. Elemental budgets indicate substantial release of base cations important for inorganic carbon removal and their accumulation mainly in the soil exchangeable pools. Geochemical reactive transport modelling, constrained by elemental budgets, indicated CO2 sequestration rates of 2–4 t CO2/ha, 1–5 years after a single application of basaltic rock dust, including via newly formed soil carbonate minerals whose long‐term fate requires assessment through field trials. This represents an approximately fourfold increase in carbon capture compared to control plant–soil systems without basalt. Our results build support for ERW deployment as a CDR technique compatible with spreading basalt powder on acidic loamy soils common across millions of hectares of western European and North American agriculture.",
keywords = "carbon removal, crop productivity, mineral weathering, negative emissions technology, reactive transport modelling, silicon, soil acidification",
author = "Kelland, {Mike E.} and Wade, {Peter W.} and Lewis, {Amy L.} and Taylor, {Lyla L.} and Binoy Sarkar and Andrews, {M. Grace} and Lomas, {Mark R.} and Cotton, {T. E. Anne} and Kemp, {Simon J.} and James, {Rachael H.} and Pearce, {Christopher R.} and Hartley, {Sue E.} and Hodson, {Mark E.} and Leake, {Jonathan R.} and Banwart, {Steven A.} and Beerling, {David J.}",
year = "2020",
month = apr,
day = "21",
doi = "10.1111/gcb.15089",
language = "English",
journal = "Global Change Biology",
issn = "1354-1013",
publisher = "Blackwell Publishing Ltd",

}

RIS

TY - JOUR

T1 - Increased yield and CO 2 sequestration potential with the C 4 cereal Sorghum bicolor cultivated in basaltic rock dust‐amended agricultural soil

AU - Kelland, Mike E.

AU - Wade, Peter W.

AU - Lewis, Amy L.

AU - Taylor, Lyla L.

AU - Sarkar, Binoy

AU - Andrews, M. Grace

AU - Lomas, Mark R.

AU - Cotton, T. E. Anne

AU - Kemp, Simon J.

AU - James, Rachael H.

AU - Pearce, Christopher R.

AU - Hartley, Sue E.

AU - Hodson, Mark E.

AU - Leake, Jonathan R.

AU - Banwart, Steven A.

AU - Beerling, David J.

PY - 2020/4/21

Y1 - 2020/4/21

N2 - Land‐based enhanced rock weathering (ERW) is a biogeochemical carbon dioxide removal (CDR) strategy aiming to accelerate natural geological processes of carbon sequestration through application of crushed silicate rocks, such as basalt, to croplands and forested landscapes. However, the efficacy of the approach when undertaken with basalt, and its potential co‐benefits for agriculture, require experimental and field evaluation. Here we report that amending a UK clay‐loam agricultural soil with a high loading (10 kg/m2) of relatively coarse‐grained crushed basalt significantly increased the yield (21 ± 9.4%, SE) of the important C4 cereal Sorghum bicolor under controlled environmental conditions, without accumulation of potentially toxic trace elements in the seeds. Yield increases resulted from the basalt treatment after 120 days without P‐ and K‐fertilizer addition. Shoot silicon concentrations also increased significantly (26 ± 5.4%, SE), with potential benefits for crop resistance to biotic and abiotic stress. Elemental budgets indicate substantial release of base cations important for inorganic carbon removal and their accumulation mainly in the soil exchangeable pools. Geochemical reactive transport modelling, constrained by elemental budgets, indicated CO2 sequestration rates of 2–4 t CO2/ha, 1–5 years after a single application of basaltic rock dust, including via newly formed soil carbonate minerals whose long‐term fate requires assessment through field trials. This represents an approximately fourfold increase in carbon capture compared to control plant–soil systems without basalt. Our results build support for ERW deployment as a CDR technique compatible with spreading basalt powder on acidic loamy soils common across millions of hectares of western European and North American agriculture.

AB - Land‐based enhanced rock weathering (ERW) is a biogeochemical carbon dioxide removal (CDR) strategy aiming to accelerate natural geological processes of carbon sequestration through application of crushed silicate rocks, such as basalt, to croplands and forested landscapes. However, the efficacy of the approach when undertaken with basalt, and its potential co‐benefits for agriculture, require experimental and field evaluation. Here we report that amending a UK clay‐loam agricultural soil with a high loading (10 kg/m2) of relatively coarse‐grained crushed basalt significantly increased the yield (21 ± 9.4%, SE) of the important C4 cereal Sorghum bicolor under controlled environmental conditions, without accumulation of potentially toxic trace elements in the seeds. Yield increases resulted from the basalt treatment after 120 days without P‐ and K‐fertilizer addition. Shoot silicon concentrations also increased significantly (26 ± 5.4%, SE), with potential benefits for crop resistance to biotic and abiotic stress. Elemental budgets indicate substantial release of base cations important for inorganic carbon removal and their accumulation mainly in the soil exchangeable pools. Geochemical reactive transport modelling, constrained by elemental budgets, indicated CO2 sequestration rates of 2–4 t CO2/ha, 1–5 years after a single application of basaltic rock dust, including via newly formed soil carbonate minerals whose long‐term fate requires assessment through field trials. This represents an approximately fourfold increase in carbon capture compared to control plant–soil systems without basalt. Our results build support for ERW deployment as a CDR technique compatible with spreading basalt powder on acidic loamy soils common across millions of hectares of western European and North American agriculture.

KW - carbon removal

KW - crop productivity

KW - mineral weathering

KW - negative emissions technology

KW - reactive transport modelling

KW - silicon

KW - soil acidification

U2 - 10.1111/gcb.15089

DO - 10.1111/gcb.15089

M3 - Journal article

JO - Global Change Biology

JF - Global Change Biology

SN - 1354-1013

ER -