Microbial communities modulate chemical weathering and carbon dioxide cycling in an active orogen in Taiwan

Pei Ling Wang; Tzu Hsuan Tu; Li Hung Lin; Hsi Ling Chou; Yi Jie Wang; Jhen Nien Chen; Lu Yu Wang; Jui Ming Chang; Mei Fei Chu; Yi Chun Hsu; Chung Pai Chang; Yih Ming Wu; Yen Tsu Lin; Chien Chung Ke

doi:10.1038/s43247-024-01345-3

Microbial communities modulate chemical weathering and carbon dioxide cycling in an active orogen in Taiwan

Pei Ling Wang, Tzu Hsuan Tu, Li Hung Lin, Hsi Ling Chou, Yi Jie Wang, Jhen Nien Chen, Lu Yu Wang, Jui Ming Chang, Mei Fei Chu, Yi Chun Hsu, Chung Pai Chang, Yih Ming Wu, Yen Tsu Lin, Chien Chung Ke

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Abstract

Chemical weathering modulates carbon transfer between the crust, hydrosphere, and atmosphere. The extent to which microbial processes are involved in mineral dissolution remains elusive. Here, we performed geochemical and molecular analyses of river water and other materials collected from a rapidly exhuming catchment in eastern Taiwan. In addition to solute generation driven primarily by pyrite-induced carbonate weathering, highly skewed microbial community compositions with abundant Sulfuricurvum and Thiobacillus members were detected during high-water periods. The yields of these taxa were also correlated with those of sulfate and sediments, suggesting that pyrite oxidation and carbonate dissolution were facilitated by sulfur-respiring microorganisms inhabiting erodible materials at a pace comparable to the supply of sulfur-bearing minerals through rapid exhumation. The net CO₂ export regulated by such potentially supply-limited, microbially-mediated mineral weathering greatly surpasses the global average, highlighting active orogens in high-standing islands as important CO₂ contributors rendered by tandem biotic and abiotic processes.

Original language	English
Article number	174
Journal	Communications Earth and Environment
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s43247-024-01345-3
State	Published - Dec 2024

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Wang, P. L., Tu, T. H., Lin, L. H., Chou, H. L., Wang, Y. J., Chen, J. N., Wang, L. Y., Chang, J. M., Chu, M. F., Hsu, Y. C., Chang, C. P., Wu, Y. M., Lin, Y. T., & Ke, C. C. (2024). Microbial communities modulate chemical weathering and carbon dioxide cycling in an active orogen in Taiwan. Communications Earth and Environment, 5(1), Article 174. https://doi.org/10.1038/s43247-024-01345-3

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abstract = "Chemical weathering modulates carbon transfer between the crust, hydrosphere, and atmosphere. The extent to which microbial processes are involved in mineral dissolution remains elusive. Here, we performed geochemical and molecular analyses of river water and other materials collected from a rapidly exhuming catchment in eastern Taiwan. In addition to solute generation driven primarily by pyrite-induced carbonate weathering, highly skewed microbial community compositions with abundant Sulfuricurvum and Thiobacillus members were detected during high-water periods. The yields of these taxa were also correlated with those of sulfate and sediments, suggesting that pyrite oxidation and carbonate dissolution were facilitated by sulfur-respiring microorganisms inhabiting erodible materials at a pace comparable to the supply of sulfur-bearing minerals through rapid exhumation. The net CO2 export regulated by such potentially supply-limited, microbially-mediated mineral weathering greatly surpasses the global average, highlighting active orogens in high-standing islands as important CO2 contributors rendered by tandem biotic and abiotic processes.",

author = "Wang, {Pei Ling} and Tu, {Tzu Hsuan} and Lin, {Li Hung} and Chou, {Hsi Ling} and Wang, {Yi Jie} and Chen, {Jhen Nien} and Wang, {Lu Yu} and Chang, {Jui Ming} and Chu, {Mei Fei} and Hsu, {Yi Chun} and Chang, {Chung Pai} and Wu, {Yih Ming} and Lin, {Yen Tsu} and Ke, {Chien Chung}",

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T1 - Microbial communities modulate chemical weathering and carbon dioxide cycling in an active orogen in Taiwan

AU - Wang, Pei Ling

AU - Tu, Tzu Hsuan

AU - Lin, Li Hung

AU - Chou, Hsi Ling

AU - Wang, Yi Jie

AU - Chen, Jhen Nien

AU - Wang, Lu Yu

AU - Chang, Jui Ming

AU - Chu, Mei Fei

AU - Hsu, Yi Chun

AU - Chang, Chung Pai

AU - Wu, Yih Ming

AU - Lin, Yen Tsu

AU - Ke, Chien Chung

PY - 2024/12

Y1 - 2024/12

N2 - Chemical weathering modulates carbon transfer between the crust, hydrosphere, and atmosphere. The extent to which microbial processes are involved in mineral dissolution remains elusive. Here, we performed geochemical and molecular analyses of river water and other materials collected from a rapidly exhuming catchment in eastern Taiwan. In addition to solute generation driven primarily by pyrite-induced carbonate weathering, highly skewed microbial community compositions with abundant Sulfuricurvum and Thiobacillus members were detected during high-water periods. The yields of these taxa were also correlated with those of sulfate and sediments, suggesting that pyrite oxidation and carbonate dissolution were facilitated by sulfur-respiring microorganisms inhabiting erodible materials at a pace comparable to the supply of sulfur-bearing minerals through rapid exhumation. The net CO2 export regulated by such potentially supply-limited, microbially-mediated mineral weathering greatly surpasses the global average, highlighting active orogens in high-standing islands as important CO2 contributors rendered by tandem biotic and abiotic processes.

AB - Chemical weathering modulates carbon transfer between the crust, hydrosphere, and atmosphere. The extent to which microbial processes are involved in mineral dissolution remains elusive. Here, we performed geochemical and molecular analyses of river water and other materials collected from a rapidly exhuming catchment in eastern Taiwan. In addition to solute generation driven primarily by pyrite-induced carbonate weathering, highly skewed microbial community compositions with abundant Sulfuricurvum and Thiobacillus members were detected during high-water periods. The yields of these taxa were also correlated with those of sulfate and sediments, suggesting that pyrite oxidation and carbonate dissolution were facilitated by sulfur-respiring microorganisms inhabiting erodible materials at a pace comparable to the supply of sulfur-bearing minerals through rapid exhumation. The net CO2 export regulated by such potentially supply-limited, microbially-mediated mineral weathering greatly surpasses the global average, highlighting active orogens in high-standing islands as important CO2 contributors rendered by tandem biotic and abiotic processes.

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VL - 5

JO - Communications Earth and Environment

JF - Communications Earth and Environment

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Microbial communities modulate chemical weathering and carbon dioxide cycling in an active orogen in Taiwan

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