Dust transport enhanced land surface weatherability in a cooling world
link https://doi.org/10.7185/geochemlet.2322account_box Yang, Y.account_box Galy, A.account_box Zhang, J.account_box Lambert, Fabriceaccount_box Zhang, M.account_box Zhang, F.account_box Fang, X.
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The weatherability of exposed silicate rocks drives the efficiency of climatic feedback on the geological carbon cycle through silicate weathering. However, the controls and evolution of land surface weatherability are not fully understood. Tectonically induced exposure of fresh silicates can induce a wide range of weatherability, depending on the maturity and lithology of the exhumed rocks. Here, we propose that aeolian dust has potentially been pivotal in sustaining land surface weatherability during global cooling. Our analysis of palaeoclimate simulations shows an additional transport of 1072 ± 69 Tg yr−1 of dust to regions with precipitation of more than 400 mm yr−1 during the Last Glacial Maximum compared to the pre-industrial period. As dust mainly contains fresh minerals with high surface areas, such dust transport markedly increases land surface weatherability, yielding an additional atmospheric CO2 consumption of 0.431 ± 0.030 Tmol yr−1, which would offset the reduced silicate weathering induced by weaker climatic forcing. It is suggested that a dustier world could increase global land surface weatherability, leading to a more buffered carbon cycle that sustained low atmospheric CO2 levels.
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| Autor | Yang, Y. Galy, A. Zhang, J. Lambert, Fabrice Zhang, M. Zhang, F. Fang, X. |
| Título | Dust transport enhanced land surface weatherability in a cooling world |
| Revista | Geochemical Perspectives Letters |
| ISSN | 2410-339X |
| ISSN electrónico | 2410-3403 |
| Volumen | 26 |
| Página inicio | 36 |
| Página final | 39 |
| Fecha de publicación | 2023 |
| Resumen | The weatherability of exposed silicate rocks drives the efficiency of climatic feedback on the geological carbon cycle through silicate weathering. However, the controls and evolution of land surface weatherability are not fully understood. Tectonically induced exposure of fresh silicates can induce a wide range of weatherability, depending on the maturity and lithology of the exhumed rocks. Here, we propose that aeolian dust has potentially been pivotal in sustaining land surface weatherability during global cooling. Our analysis of palaeoclimate simulations shows an additional transport of 1072 ± 69 Tg yr−1 of dust to regions with precipitation of more than 400 mm yr−1 during the Last Glacial Maximum compared to the pre-industrial period. As dust mainly contains fresh minerals with high surface areas, such dust transport markedly increases land surface weatherability, yielding an additional atmospheric CO2 consumption of 0.431 ± 0.030 Tmol yr−1, which would offset the reduced silicate weathering induced by weaker climatic forcing. It is suggested that a dustier world could increase global land surface weatherability, leading to a more buffered carbon cycle that sustained low atmospheric CO2 levels. |
| Derechos | acceso abierto |
| Licencia | Atribución-NoComercial-SinDerivadas 4.0 Internacional (CC BY-NC-ND 4.0) |
| Agencia financiadora | Second Tibetan Plateau Scientific Expedition and Research National Natural Science Foundation of China FONDECYT National Key Research and Development Program of China FONDAP |
| DOI | 10.7185/geochemlet.2322 |
| Editorial | European Association of Geochemistry |
| Enlace | |
| Id de publicación en Scopus | SCOPUS_ID:85168162352 |
| Id de publicación en WoS | WOS:001074289000001 |
| Palabra clave | Carbon cycle Cooling Dust Land surface Last Glacial Maximum Paleoclimate Precipitation (climatology) Eolian deposit |
| Tema ODS | 06 Clean water and sanitation |
| Tema ODS español | 06 Agua limpia y saneamiento |
| Temática | Ciencias de la tierra |
| Tipo de documento | artículo |