A revised model of global silicate weathering considering the influence of vegetation cover on erosion rate

• Published in: Geoscientific Model Development Vol. 17; no. 9; pp. 3949 - 3974
• Main Authors: Zuo, Haoyue, Liu, Yonggang, Li, Gaojun, Xu, Zhifang, Zhao, Liang, Guo, Zhengtang, Hu, Yongyun
• Format: Journal Article
• Language: English
• Published: Katlenburg-Lindau Copernicus GmbH 15.05.2024; Copernicus Publications
• Subjects: Analysis; Biogeochemical cycle; Biogeochemical cycles; Carbon cycle; Carbon cycle (Biogeochemistry); Carbon sequestration; Climate; Climate and vegetation; Climate change; Data comparison; Erosion rates; Geomorphology; Leaching; Leaf area; Leaf area index; Outgassing; Parameterization; Plant cover; Rivers; Silicates; Soil erosion; Stream discharge; Stream flow; Tectonics; Transfer functions; Tropical environment; Tropical environments; Uncertainty; Vegetation; Vegetation cover; Vegetation effects; Weathering
• ISSN: 1991-9603; 1991-959X; 1991-962X; 1991-9603; 1991-962X
• DOI: 10.5194/gmd-17-3949-2024

Silicate weathering, which is of great importance in regulating the global carbon cycle, has been found to be affected by complicated factors, including climate, tectonics and vegetation. However, the exact transfer function between these factors and the silicate weathering rate is still unclear, leading to large model–data discrepancies in the CO2 consumption associated with silicate weathering. Here we propose a simple parameterization for the influence of vegetation cover on erosion rate to improve the model–data comparison based on a state-of-the-art silicate weathering model. We found out that the current weathering model tends to overestimate the silicate weathering fluxes in the tropical region, which can hardly be explained by either the uncertainties in climate and geomorphological conditions or the optimization of model parameters. We show that such an overestimation of the tropical weathering rate can be rectified significantly by parameterizing the shielding effect of vegetation cover on soil erosion using the leaf area index (LAI), the high values of which are coincident with the distribution of leached soils. We propose that the heavy vegetation in the tropical region likely slows down the erosion rate, much more so than thought before, by reducing extreme streamflow in response to precipitation. The silicate weathering model thus revised gives a smaller global weathering flux which is arguably more consistent with the observed value and the recently reconstructed global outgassing, both of which are subject to uncertainties. The model is also easily applicable to the deep-time Earth to investigate the influence of land plants on the global biogeochemical cycle.