Effects of carbonate minerals and exogenous acids on carbon flux from the chemical weathering of granite and basalt

Chaojun Li; Pete Smith; Xiaoyong Bai; Qiu Tan; Guangjie Luo; Qin Li; Jinfeng Wang; Luhua Wu; Fei Chen; Yuanhong Deng; Zeyin Hu; Yujie Yang; Shiqi Tian; Qian Lu; Huipeng Xi; Chen Ran; Sirui Zhang

doi:10.1016/j.gloplacha.2023.104053

Effects of carbonate minerals and exogenous acids on carbon flux from the chemical weathering of granite and basalt

Chaojun Li, Pete Smith, Xiaoyong Bai^* (Corresponding Author), Qiu Tan, Guangjie Luo, Qin Li, Jinfeng Wang, Luhua Wu, Fei Chen, Yuanhong Deng, Zeyin Hu, Yujie Yang, Shiqi Tian, Qian Lu, Huipeng Xi, Chen Ran, Sirui Zhang

^*Corresponding author for this work

Aberdeen Centre For Environmental Sustainability

Research output: Contribution to journal › Article › peer-review

20 Citations (Scopus)

Abstract

The chemical weathering of silicate rocks can yield bicarbonate which is transported via rivers to the ocean, followed by the deposition of carbonate, acting as a carbon sink on long time scales. The dissolution of carbonate minerals and the participation of exogenous acids (e.g., sulfuric acid and nitric acid) also affect the chemical weathering process. However, their effects have rarely been quantified at the global scale. Here, based on a compilation of time series datasets of hydro-chemistry samples from 3573 monitoring sites and high-resolution hydro-meteorological datasets, we quantified the effects of carbonate minerals and exogenous acids on the carbon fluxes from the chemical weathering of granite and basalt. The calculated true carbon fluxes of the chemical weathering of granite and basalt were approximately 28.72 Tg C/yr and 30.42 Tg C/yr on the global grid scale. Although the effects of exogenous acids to the true carbon fluxes of the chemical weathering from granite and basalt were similar, corresponding to 30% and 28% of the estimated cation fluxes, respectively, the effect of carbonate minerals on the chemical weathering of granite was approximately twice the effect on the chemical weathering of basalt. These discrepancies were caused by the differences in the chemical weathering characteristics and the laws that integrated the different effects of basalt and granite. Our results address the roles of carbonate minerals and exogenous acids in the global carbon cycle and their link to CO2 consumption via the chemical weathering of silicate rocks.

Original language	English
Article number	104053
Number of pages	12
Journal	Global and Planetary Change
Volume	221
Early online date	31 Jan 2023
DOIs	https://doi.org/10.1016/j.gloplacha.2023.104053
Publication status	Published - Feb 2023

Bibliographical note

Acknowledgments
This work was supported jointly by the Western Light Cross-team Program of Chinese Academy of Sciences (No. xbzg-zdsys-202101); National Natural Science Foundation of China (No. 42077455 & No.42167032); Strategic Priority Research Program of the Chinese Academy of Sciences (No. XDB40000000 & No. XDA23060100); Guizhou Provincial Science and Technology Projects (No. Qiankehe Support [2022] General 198); High-level innovative talents in Guizhou Province (No. GCC[2022]015-1 & No. 2016-5648); Guizhou Provincial 2020 Science and Technology Subsidies (No. GZ2020SIG); the Opening Fund of the State Key Laboratory of Environmental Geochemistry (No. SKLEG2022206 & No. SKLEG2022208); and the central government leading local science and technology development (No. QianKeZhongYinDi [2021]4028). We thank the editors and all anonymous reviewers for their constructive comments. Special thanks to Prof. Gaillardet (Institut de Physique du Globe de Paris), Prof. Ibarra (Brown University), and Dr. Bufe (German Research Center for Geosciences (GFZ)) for their constructive suggestions. Thanks to the originator of the hydrochemical datasets acquired through UN Environment GEMS/Water Programme. We thank LetPub (www.letpub.com) for its linguistic assistance during the preparation of this manuscript.

Data Availability Statement

Data Availability
The hydrochemical datasets related to this article are from the GLObal RIver CHemistry (GLORICH) database (https://doi.pangaea.de/10.1594/PANGAEA.902360), the GEMS-GLORI database (https://doi.pangaea.de/10.1594/PANGAEA.804574) and the GEMS/ Water data center. Among them, the hydrochemical data from GEMS/water data center needs to be used by custom data request (https://gemstat.org/custom-data-request/). Rock samples of granite and basalt are from the Geochemistry Library (ECL), and the specific data is stored in PetDB database, which is a searchable database of published geochemical data (https://search.earthchem.org/setsampletype?pkey=3404938).Supplementary data to this article can be found online at https://doi.org/10.1016/j.gloplacha.2023.104053.

Supplementary Data
Supplementary data to this article can be found online at https://doi.
org/10.1016/j.gloplacha.2023.104053.

Keywords

Carbon sink
Carbonate minerals
Climate change
Rock weathering
Silicate

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Li, C., Smith, P., Bai, X., Tan, Q., Luo, G., Li, Q., Wang, J., Wu, L., Chen, F., Deng, Y., Hu, Z., Yang, Y., Tian, S., Lu, Q., Xi, H., Ran, C., & Zhang, S. (2023). Effects of carbonate minerals and exogenous acids on carbon flux from the chemical weathering of granite and basalt. Global and Planetary Change, 221, Article 104053. https://doi.org/10.1016/j.gloplacha.2023.104053

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title = "Effects of carbonate minerals and exogenous acids on carbon flux from the chemical weathering of granite and basalt",

abstract = "The chemical weathering of silicate rocks can yield bicarbonate which is transported via rivers to the ocean, followed by the deposition of carbonate, acting as a carbon sink on long time scales. The dissolution of carbonate minerals and the participation of exogenous acids (e.g., sulfuric acid and nitric acid) also affect the chemical weathering process. However, their effects have rarely been quantified at the global scale. Here, based on a compilation of time series datasets of hydro-chemistry samples from 3573 monitoring sites and high-resolution hydro-meteorological datasets, we quantified the effects of carbonate minerals and exogenous acids on the carbon fluxes from the chemical weathering of granite and basalt. The calculated true carbon fluxes of the chemical weathering of granite and basalt were approximately 28.72 Tg C/yr and 30.42 Tg C/yr on the global grid scale. Although the effects of exogenous acids to the true carbon fluxes of the chemical weathering from granite and basalt were similar, corresponding to 30% and 28% of the estimated cation fluxes, respectively, the effect of carbonate minerals on the chemical weathering of granite was approximately twice the effect on the chemical weathering of basalt. These discrepancies were caused by the differences in the chemical weathering characteristics and the laws that integrated the different effects of basalt and granite. Our results address the roles of carbonate minerals and exogenous acids in the global carbon cycle and their link to CO2 consumption via the chemical weathering of silicate rocks.",

keywords = "Carbon sink, Carbonate minerals, Climate change, Rock weathering, Silicate",

author = "Chaojun Li and Pete Smith and Xiaoyong Bai and Qiu Tan and Guangjie Luo and Qin Li and Jinfeng Wang and Luhua Wu and Fei Chen and Yuanhong Deng and Zeyin Hu and Yujie Yang and Shiqi Tian and Qian Lu and Huipeng Xi and Chen Ran and Sirui Zhang",

note = "Acknowledgments This work was supported jointly by the Western Light Cross-team Program of Chinese Academy of Sciences (No. xbzg-zdsys-202101); National Natural Science Foundation of China (No. 42077455 & No.42167032); Strategic Priority Research Program of the Chinese Academy of Sciences (No. XDB40000000 & No. XDA23060100); Guizhou Provincial Science and Technology Projects (No. Qiankehe Support [2022] General 198); High-level innovative talents in Guizhou Province (No. GCC[2022]015-1 & No. 2016-5648); Guizhou Provincial 2020 Science and Technology Subsidies (No. GZ2020SIG); the Opening Fund of the State Key Laboratory of Environmental Geochemistry (No. SKLEG2022206 & No. SKLEG2022208); and the central government leading local science and technology development (No. QianKeZhongYinDi [2021]4028). We thank the editors and all anonymous reviewers for their constructive comments. Special thanks to Prof. Gaillardet (Institut de Physique du Globe de Paris), Prof. Ibarra (Brown University), and Dr. Bufe (German Research Center for Geosciences (GFZ)) for their constructive suggestions. Thanks to the originator of the hydrochemical datasets acquired through UN Environment GEMS/Water Programme. We thank LetPub (www.letpub.com) for its linguistic assistance during the preparation of this manuscript. ",

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T1 - Effects of carbonate minerals and exogenous acids on carbon flux from the chemical weathering of granite and basalt

AU - Li, Chaojun

AU - Smith, Pete

AU - Bai, Xiaoyong

AU - Tan, Qiu

AU - Luo, Guangjie

AU - Li, Qin

AU - Wang, Jinfeng

AU - Wu, Luhua

AU - Chen, Fei

AU - Deng, Yuanhong

AU - Hu, Zeyin

AU - Yang, Yujie

AU - Tian, Shiqi

AU - Lu, Qian

AU - Xi, Huipeng

AU - Ran, Chen

AU - Zhang, Sirui

N1 - Acknowledgments This work was supported jointly by the Western Light Cross-team Program of Chinese Academy of Sciences (No. xbzg-zdsys-202101); National Natural Science Foundation of China (No. 42077455 & No.42167032); Strategic Priority Research Program of the Chinese Academy of Sciences (No. XDB40000000 & No. XDA23060100); Guizhou Provincial Science and Technology Projects (No. Qiankehe Support [2022] General 198); High-level innovative talents in Guizhou Province (No. GCC[2022]015-1 & No. 2016-5648); Guizhou Provincial 2020 Science and Technology Subsidies (No. GZ2020SIG); the Opening Fund of the State Key Laboratory of Environmental Geochemistry (No. SKLEG2022206 & No. SKLEG2022208); and the central government leading local science and technology development (No. QianKeZhongYinDi [2021]4028). We thank the editors and all anonymous reviewers for their constructive comments. Special thanks to Prof. Gaillardet (Institut de Physique du Globe de Paris), Prof. Ibarra (Brown University), and Dr. Bufe (German Research Center for Geosciences (GFZ)) for their constructive suggestions. Thanks to the originator of the hydrochemical datasets acquired through UN Environment GEMS/Water Programme. We thank LetPub (www.letpub.com) for its linguistic assistance during the preparation of this manuscript.

PY - 2023/2

Y1 - 2023/2

N2 - The chemical weathering of silicate rocks can yield bicarbonate which is transported via rivers to the ocean, followed by the deposition of carbonate, acting as a carbon sink on long time scales. The dissolution of carbonate minerals and the participation of exogenous acids (e.g., sulfuric acid and nitric acid) also affect the chemical weathering process. However, their effects have rarely been quantified at the global scale. Here, based on a compilation of time series datasets of hydro-chemistry samples from 3573 monitoring sites and high-resolution hydro-meteorological datasets, we quantified the effects of carbonate minerals and exogenous acids on the carbon fluxes from the chemical weathering of granite and basalt. The calculated true carbon fluxes of the chemical weathering of granite and basalt were approximately 28.72 Tg C/yr and 30.42 Tg C/yr on the global grid scale. Although the effects of exogenous acids to the true carbon fluxes of the chemical weathering from granite and basalt were similar, corresponding to 30% and 28% of the estimated cation fluxes, respectively, the effect of carbonate minerals on the chemical weathering of granite was approximately twice the effect on the chemical weathering of basalt. These discrepancies were caused by the differences in the chemical weathering characteristics and the laws that integrated the different effects of basalt and granite. Our results address the roles of carbonate minerals and exogenous acids in the global carbon cycle and their link to CO2 consumption via the chemical weathering of silicate rocks.

AB - The chemical weathering of silicate rocks can yield bicarbonate which is transported via rivers to the ocean, followed by the deposition of carbonate, acting as a carbon sink on long time scales. The dissolution of carbonate minerals and the participation of exogenous acids (e.g., sulfuric acid and nitric acid) also affect the chemical weathering process. However, their effects have rarely been quantified at the global scale. Here, based on a compilation of time series datasets of hydro-chemistry samples from 3573 monitoring sites and high-resolution hydro-meteorological datasets, we quantified the effects of carbonate minerals and exogenous acids on the carbon fluxes from the chemical weathering of granite and basalt. The calculated true carbon fluxes of the chemical weathering of granite and basalt were approximately 28.72 Tg C/yr and 30.42 Tg C/yr on the global grid scale. Although the effects of exogenous acids to the true carbon fluxes of the chemical weathering from granite and basalt were similar, corresponding to 30% and 28% of the estimated cation fluxes, respectively, the effect of carbonate minerals on the chemical weathering of granite was approximately twice the effect on the chemical weathering of basalt. These discrepancies were caused by the differences in the chemical weathering characteristics and the laws that integrated the different effects of basalt and granite. Our results address the roles of carbonate minerals and exogenous acids in the global carbon cycle and their link to CO2 consumption via the chemical weathering of silicate rocks.

KW - Carbon sink

KW - Carbonate minerals

KW - Climate change

KW - Rock weathering

KW - Silicate

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DO - 10.1016/j.gloplacha.2023.104053

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VL - 221

JO - Global and Planetary Change

JF - Global and Planetary Change

M1 - 104053

ER -

Effects of carbonate minerals and exogenous acids on carbon flux from the chemical weathering of granite and basalt

Abstract

Bibliographical note

Data Availability Statement

Keywords

UN SDGs

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