Applying minerals to soil to draw down atmospheric carbon dioxide through synergistic organic and inorganic pathways
Applying minerals to soil to draw down atmospheric carbon dioxide through synergistic organic and inorganic pathways
Minerals in soil can sequester atmospheric carbon dioxide through natural organic and inorganic processes. Here we consider three soil- and mineral-based methods for carbon dioxide removal: (1) grinding and spreading of calcium- and magnesium-rich silicate rocks for enhanced rock weathering and subsequent inorganic carbon formation, (2) mineral doping of biomass prior to conversion into biochar for enhanced biochar carbon yield and stability, and (3) strategic application of minerals to soil to increase soil organic carbon accrual and stability. We argue that there are powerful synergies between these approaches for carbon dioxide removal through organic and inorganic pathways. We find that primary silicates, as contained in basalt, can benefit both enhanced weathering and soil organic carbon formation, while phyllosilicates and other reactive secondary minerals may have positive synergies for biochar and soil organic carbon. Optimising such synergies may substantially enhance economic and environmental benefits, yet these synergies require accurate quantification.
Buss, Wolfram
942bb03b-829f-4604-9ca8-b26c69e8e2e4
Hasemer, Heath
757b27be-835b-4a92-b51b-12dc8389b198
Sokol, Noah W.
3f9f1444-3883-4c56-82de-bb4b6e2eae6e
Rohling, Eelco J.
a2a27ef2-fcce-4c71-907b-e692b5ecc685
Borevitz, Justin
3b413275-0ff7-40d9-873f-ec18445fe3eb
18 October 2024
Buss, Wolfram
942bb03b-829f-4604-9ca8-b26c69e8e2e4
Hasemer, Heath
757b27be-835b-4a92-b51b-12dc8389b198
Sokol, Noah W.
3f9f1444-3883-4c56-82de-bb4b6e2eae6e
Rohling, Eelco J.
a2a27ef2-fcce-4c71-907b-e692b5ecc685
Borevitz, Justin
3b413275-0ff7-40d9-873f-ec18445fe3eb
Buss, Wolfram, Hasemer, Heath, Sokol, Noah W., Rohling, Eelco J. and Borevitz, Justin
(2024)
Applying minerals to soil to draw down atmospheric carbon dioxide through synergistic organic and inorganic pathways.
Communications Earth & Environment, 5, [602].
(doi:10.1038/s43247-024-01771-3).
Abstract
Minerals in soil can sequester atmospheric carbon dioxide through natural organic and inorganic processes. Here we consider three soil- and mineral-based methods for carbon dioxide removal: (1) grinding and spreading of calcium- and magnesium-rich silicate rocks for enhanced rock weathering and subsequent inorganic carbon formation, (2) mineral doping of biomass prior to conversion into biochar for enhanced biochar carbon yield and stability, and (3) strategic application of minerals to soil to increase soil organic carbon accrual and stability. We argue that there are powerful synergies between these approaches for carbon dioxide removal through organic and inorganic pathways. We find that primary silicates, as contained in basalt, can benefit both enhanced weathering and soil organic carbon formation, while phyllosilicates and other reactive secondary minerals may have positive synergies for biochar and soil organic carbon. Optimising such synergies may substantially enhance economic and environmental benefits, yet these synergies require accurate quantification.
Text
s43247-024-01771-3
- Version of Record
More information
Accepted/In Press date: 8 October 2024
Published date: 18 October 2024
Identifiers
Local EPrints ID: 504170
URI: http://eprints.soton.ac.uk/id/eprint/504170
PURE UUID: 56abcb69-4178-447c-b862-eab66821878d
Catalogue record
Date deposited: 28 Aug 2025 16:41
Last modified: 29 Aug 2025 01:35
Export record
Altmetrics
Contributors
Author:
Wolfram Buss
Author:
Heath Hasemer
Author:
Noah W. Sokol
Author:
Justin Borevitz
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
