Global silicate weathering flux overestimated because of sediment–water cation exchange
Global silicate weathering flux overestimated because of sediment–water cation exchange
Rivers carry the dissolved and solid products of silicate mineral weathering, a process that removes CO2 from the atmosphere and provides a key negative climate feedback over geological timescales. Here we show that, in some river systems, a reactive exchange pool on river suspended particulate matter, bonded weakly to mineral surfaces, increases the mobile cation flux by 50%. The chemistry of both river waters and the exchange pool demonstrates exchange equilibrium, confirmed by Sr isotopes. Global silicate weathering fluxes are calculated based on riverine dissolved sodium (Na+) from silicate minerals. The large exchange pool supplies Na+ of nonsilicate origin to the dissolved load, especially in catchments with widespread marine sediments, or where rocks have equilibrated with saline basement fluids. We quantify this by comparing the riverine sediment exchange pool and river water chemistry. In some basins, cation exchange could account for the majority of sodium in the river water, significantly reducing estimates of silicate weathering. At a global scale, we demonstrate that silicate weathering fluxes are overestimated by 12 to 28%. This overestimation is greatest in regions of high erosion and high sediment loads where the negative climate feedback has a maximum sensitivity to chemical weathering reactions. In the context of other recent findings that reduce the net CO2 consumption through chemical weathering, the magnitude of the continental silicate weathering fluxes and its implications for solid Earth CO2 degassing fluxes need to be further investigated.
Tipper, Edward T.
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Stevenson, Emily I.
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Alcock, Victoria
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Knight, Alasdair C. G.
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Baronas, J. Jotautas
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Hilton, Robert G.
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Bickle, Mike J.
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Larkin, Christina S.
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Feng, Linshu
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Relph, Katy E.
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Hughes, Genevieve
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5 January 2021
Tipper, Edward T.
b966fdef-6e38-40dd-b22e-c529f4b974d0
Stevenson, Emily I.
d6f2e095-ee90-4acf-b9a1-66dcfeb12b7e
Alcock, Victoria
6b92318e-39a5-47b9-9f28-402ddc4a8bc3
Knight, Alasdair C. G.
dcf65291-133f-47d9-8cd1-fdd150e2e61e
Baronas, J. Jotautas
9c9473d9-6376-4dc7-b940-ee6d0427ef01
Hilton, Robert G.
63b6109b-020f-4cdd-8c16-7a8137f9343a
Bickle, Mike J.
101a3535-9edd-4219-8507-9cf06f71f08f
Larkin, Christina S.
7e5477b9-0a3d-4580-ba78-2e6282f010cc
Feng, Linshu
27af678b-551d-472a-b373-3dde6fafc2fd
Relph, Katy E.
b572d543-7acd-413a-84ae-7a88842b0c5c
Hughes, Genevieve
deb0fa69-f07b-4a6c-8a84-16bec81a6d2b
Tipper, Edward T., Stevenson, Emily I., Alcock, Victoria, Knight, Alasdair C. G., Baronas, J. Jotautas, Hilton, Robert G., Bickle, Mike J., Larkin, Christina S., Feng, Linshu, Relph, Katy E. and Hughes, Genevieve
(2021)
Global silicate weathering flux overestimated because of sediment–water cation exchange.
Proceedings of the National Academy of Sciences, 118 (1).
(doi:10.1073/pnas.2016430118).
Abstract
Rivers carry the dissolved and solid products of silicate mineral weathering, a process that removes CO2 from the atmosphere and provides a key negative climate feedback over geological timescales. Here we show that, in some river systems, a reactive exchange pool on river suspended particulate matter, bonded weakly to mineral surfaces, increases the mobile cation flux by 50%. The chemistry of both river waters and the exchange pool demonstrates exchange equilibrium, confirmed by Sr isotopes. Global silicate weathering fluxes are calculated based on riverine dissolved sodium (Na+) from silicate minerals. The large exchange pool supplies Na+ of nonsilicate origin to the dissolved load, especially in catchments with widespread marine sediments, or where rocks have equilibrated with saline basement fluids. We quantify this by comparing the riverine sediment exchange pool and river water chemistry. In some basins, cation exchange could account for the majority of sodium in the river water, significantly reducing estimates of silicate weathering. At a global scale, we demonstrate that silicate weathering fluxes are overestimated by 12 to 28%. This overestimation is greatest in regions of high erosion and high sediment loads where the negative climate feedback has a maximum sensitivity to chemical weathering reactions. In the context of other recent findings that reduce the net CO2 consumption through chemical weathering, the magnitude of the continental silicate weathering fluxes and its implications for solid Earth CO2 degassing fluxes need to be further investigated.
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Published date: 5 January 2021
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Local EPrints ID: 455846
URI: http://eprints.soton.ac.uk/id/eprint/455846
ISSN: 0027-8424
PURE UUID: ece18230-fa81-4a0a-94e6-bbaae108e421
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Date deposited: 06 Apr 2022 16:53
Last modified: 17 Mar 2024 04:05
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Author:
Edward T. Tipper
Author:
Emily I. Stevenson
Author:
Victoria Alcock
Author:
Alasdair C. G. Knight
Author:
J. Jotautas Baronas
Author:
Robert G. Hilton
Author:
Mike J. Bickle
Author:
Christina S. Larkin
Author:
Linshu Feng
Author:
Katy E. Relph
Author:
Genevieve Hughes
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