What controls the hydrochemical compositions of mountainous river water in a glacierized catchment?

Chemical weathering processes has become a growing issue in research on carbon cycling, however, mineral weathering by sulfuric acid and carbonic acid and its possible impacts on carbon cycle are yet unknown over the typical glacial catchment. To investigate the mechanisms of mineral weathering proc...

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Published inHydrological processes Vol. 37; no. 9
Main Authors Shi, Xiaoyi, Kong, Yanlong, Pu, Tao, Wang, Ke, Peng, Peiyi, Ma, Yanwei
Format Journal Article
LanguageEnglish
Published Chichester Wiley Subscription Services, Inc 01.09.2023
Subjects
Calcium
Calcium ions
Carbon
Carbon cycle
Carbon cycle models
Carbonates
Carbonic acid
Catchments
Chemical weathering
China
Composition
Dissolution
Dissolving
Downstream
Glaciers
global carbon budget
Hydrochemicals
hydrochemistry
irrigation
Magnesium
Minerals
monsoon season
Monsoons
mountains
River water
River water chemistry
Rivers
Salinity
Seasons
Solutes
Spatial variations
Stoichiometry
Sulfuric acid
Sulphuric acid
Temporal variations
Upstream
Watersheds
Weathering
Wind
China
Online AccessGet full text
ISSN0885-6087
1099-1085
DOI10.1002/hyp.14993

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Abstract Chemical weathering processes has become a growing issue in research on carbon cycling, however, mineral weathering by sulfuric acid and carbonic acid and its possible impacts on carbon cycle are yet unknown over the typical glacial catchment. To investigate the mechanisms of mineral weathering processes and its influence, the spatial–temporal variations of the major ions in Mingyong River, a glacier‐originated river located on the southeastern edge of the Qinghai‐Tibetan Plateau, were investigated. The seasonal and spatial variations in river solutes were resulted from the hydrological conditions and different mineral weathering rates. The results showed that the major ion compositions of the river waters were characterized by the dominance of Ca 2+ , Mg 2+ , HCO 3 − , with a significantly rich in SO 4 2− . A systematic increase in ionic concentrations (apart from NH 4 + and NO 3 − ) was observed in the river water from non‐monsoon to monsoon season as well as from upstream to downstream. Piper diagram results showed 100% (upstream‐midstream) and 72.5% (downstream) contributions to Ca‐HCO 3 type, respectively, indicating that a dominated carbonate weathering to the river chemistry. The (Ca 2+ +Mg 2+ )/HCO 3 − against (SO 4 2− /HCO 3 − ) scatter suggested that sulfuric and carbonic acid are responsible for chemical weathering. An increased contributions of sulfuric acid from upstream (43%) to downstream (87.3%) on the (Ca 2+ +Mg 2+ ) and from upstream (29.6%) to downstream (88.3%) on HCO 3 − using the stoichiometry analysis during the monsoon season. Contrarily, H 2 SO 4 ‐related dissolution (>65%) processes controlled the carbonate weathering during the non‐monsoon season, which indicated that sulfuric acid played a significant part in the process of rock dissolution that intensifies weathering. The effects of accelerated weathering on drinking and irrigation suitability suggested that the Mingyong River water is subject to a salinity hazard. This research demonstrates that the weathering of catchments involving sulfuric acid has the potential to alter carbon cycle and should be considered in global carbon cycle models.
AbstractList Chemical weathering processes has become a growing issue in research on carbon cycling, however, mineral weathering by sulfuric acid and carbonic acid and its possible impacts on carbon cycle are yet unknown over the typical glacial catchment. To investigate the mechanisms of mineral weathering processes and its influence, the spatial–temporal variations of the major ions in Mingyong River, a glacier‐originated river located on the southeastern edge of the Qinghai‐Tibetan Plateau, were investigated. The seasonal and spatial variations in river solutes were resulted from the hydrological conditions and different mineral weathering rates. The results showed that the major ion compositions of the river waters were characterized by the dominance of Ca2+, Mg2+, HCO3−, with a significantly rich in SO42−. A systematic increase in ionic concentrations (apart from NH4+ and NO3−) was observed in the river water from non‐monsoon to monsoon season as well as from upstream to downstream. Piper diagram results showed 100% (upstream‐midstream) and 72.5% (downstream) contributions to Ca‐HCO3 type, respectively, indicating that a dominated carbonate weathering to the river chemistry. The (Ca2++Mg2+)/HCO3− against (SO42−/HCO3−) scatter suggested that sulfuric and carbonic acid are responsible for chemical weathering. An increased contributions of sulfuric acid from upstream (43%) to downstream (87.3%) on the (Ca2++Mg2+) and from upstream (29.6%) to downstream (88.3%) on HCO3− using the stoichiometry analysis during the monsoon season. Contrarily, H2SO4‐related dissolution (>65%) processes controlled the carbonate weathering during the non‐monsoon season, which indicated that sulfuric acid played a significant part in the process of rock dissolution that intensifies weathering. The effects of accelerated weathering on drinking and irrigation suitability suggested that the Mingyong River water is subject to a salinity hazard. This research demonstrates that the weathering of catchments involving sulfuric acid has the potential to alter carbon cycle and should be considered in global carbon cycle models.
Chemical weathering processes has become a growing issue in research on carbon cycling, however, mineral weathering by sulfuric acid and carbonic acid and its possible impacts on carbon cycle are yet unknown over the typical glacial catchment. To investigate the mechanisms of mineral weathering processes and its influence, the spatial–temporal variations of the major ions in Mingyong River, a glacier‐originated river located on the southeastern edge of the Qinghai‐Tibetan Plateau, were investigated. The seasonal and spatial variations in river solutes were resulted from the hydrological conditions and different mineral weathering rates. The results showed that the major ion compositions of the river waters were characterized by the dominance of Ca 2+ , Mg 2+ , HCO 3 − , with a significantly rich in SO 4 2− . A systematic increase in ionic concentrations (apart from NH 4 + and NO 3 − ) was observed in the river water from non‐monsoon to monsoon season as well as from upstream to downstream. Piper diagram results showed 100% (upstream‐midstream) and 72.5% (downstream) contributions to Ca‐HCO 3 type, respectively, indicating that a dominated carbonate weathering to the river chemistry. The (Ca 2+ +Mg 2+ )/HCO 3 − against (SO 4 2− /HCO 3 − ) scatter suggested that sulfuric and carbonic acid are responsible for chemical weathering. An increased contributions of sulfuric acid from upstream (43%) to downstream (87.3%) on the (Ca 2+ +Mg 2+ ) and from upstream (29.6%) to downstream (88.3%) on HCO 3 − using the stoichiometry analysis during the monsoon season. Contrarily, H 2 SO 4 ‐related dissolution (>65%) processes controlled the carbonate weathering during the non‐monsoon season, which indicated that sulfuric acid played a significant part in the process of rock dissolution that intensifies weathering. The effects of accelerated weathering on drinking and irrigation suitability suggested that the Mingyong River water is subject to a salinity hazard. This research demonstrates that the weathering of catchments involving sulfuric acid has the potential to alter carbon cycle and should be considered in global carbon cycle models.
Chemical weathering processes has become a growing issue in research on carbon cycling, however, mineral weathering by sulfuric acid and carbonic acid and its possible impacts on carbon cycle are yet unknown over the typical glacial catchment. To investigate the mechanisms of mineral weathering processes and its influence, the spatial–temporal variations of the major ions in Mingyong River, a glacier‐originated river located on the southeastern edge of the Qinghai‐Tibetan Plateau, were investigated. The seasonal and spatial variations in river solutes were resulted from the hydrological conditions and different mineral weathering rates. The results showed that the major ion compositions of the river waters were characterized by the dominance of Ca²⁺, Mg²⁺, HCO₃⁻, with a significantly rich in SO₄²⁻. A systematic increase in ionic concentrations (apart from NH₄⁺ and NO₃⁻) was observed in the river water from non‐monsoon to monsoon season as well as from upstream to downstream. Piper diagram results showed 100% (upstream‐midstream) and 72.5% (downstream) contributions to Ca‐HCO₃ type, respectively, indicating that a dominated carbonate weathering to the river chemistry. The (Ca²⁺+Mg²⁺)/HCO₃⁻ against (SO₄²⁻/HCO₃⁻) scatter suggested that sulfuric and carbonic acid are responsible for chemical weathering. An increased contributions of sulfuric acid from upstream (43%) to downstream (87.3%) on the (Ca²⁺+Mg²⁺) and from upstream (29.6%) to downstream (88.3%) on HCO₃⁻ using the stoichiometry analysis during the monsoon season. Contrarily, H₂SO₄‐related dissolution (>65%) processes controlled the carbonate weathering during the non‐monsoon season, which indicated that sulfuric acid played a significant part in the process of rock dissolution that intensifies weathering. The effects of accelerated weathering on drinking and irrigation suitability suggested that the Mingyong River water is subject to a salinity hazard. This research demonstrates that the weathering of catchments involving sulfuric acid has the potential to alter carbon cycle and should be considered in global carbon cycle models.
Author Kong, Yanlong
Peng, Peiyi
Pu, Tao
Wang, Ke
Ma, Yanwei
Shi, Xiaoyi
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  organization: College of Geography and Environment Sciences Zhejiang Normal University Jinhua China
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Snippet Chemical weathering processes has become a growing issue in research on carbon cycling, however, mineral weathering by sulfuric acid and carbonic acid and its...
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SubjectTerms Calcium
Calcium ions
Carbon
Carbon cycle
Carbon cycle models
Carbonates
Carbonic acid
Catchments
Chemical weathering
China
Composition
Dissolution
Dissolving
Downstream
Glaciers
global carbon budget
Hydrochemicals
hydrochemistry
irrigation
Magnesium
Minerals
monsoon season
Monsoons
mountains
River water
River water chemistry
Rivers
Salinity
Seasons
Solutes
Spatial variations
Stoichiometry
Sulfuric acid
Sulphuric acid
Temporal variations
Upstream
Watersheds
Weathering
Wind
Title What controls the hydrochemical compositions of mountainous river water in a glacierized catchment?
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