Chemical and Isotopic Characters of the Water and Suspended Particulate Materials in the Yellow River and Their Geological and Environmental Implications
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This work was supported by the National Natural Science Foundation of China (Item No. 40673005), the Ministry of Science and Technology (Item No. 2004DIB3J081) and the Geological Survey of China (Item No. 200320130–006). We are grateful for the help of many persons of CWRC on water sample collection. We would like to thank Prof. Jiang Shaoyong for his comments and suggestions on the manuscript and his help on Sr isotope analyses. We would like to thank Prof. Wen Hongli and Miss. Xia Yuelian for their help on chemical analyses.


Chemical and Isotopic Characters of the Water and Suspended Particulate Materials in the Yellow River and Their Geological and Environmental Implications
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This work was supported by the National Natural Science Foundation of China (Item No. 40673005), the Ministry of Science and Technology (Item No. 2004DIB3J081) and the Geological Survey of China (Item No. 200320130–006). We are grateful for the help of many persons of CWRC on water sample collection. We would like to thank Prof. Jiang Shaoyong for his comments and suggestions on the manuscript and his help on Sr isotope analyses. We would like to thank Prof. Wen Hongli and Miss. Xia Yuelian for their help on chemical analyses.

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    摘要:

    The chemical and isotopic characteristics of the water and suspended particulate materials (SPM) in the Yellow River were investigated on the samples collected from 29 hydrological monitoring stations in the mainstem and several major tributaries during 2004 to 2007. The δD and δ18O values of the Yellow River water vary in large ranges from ?32‰ to ?91‰ and from ?3.1‰ to ?12.5‰, respectively. The characters of H and O isotope variations indicate that the major sources of the Yellow River water are meteoric water and snow melting water, and water cycle in the Yellow River basin is affected strongly by evaporation process and human activity. The average SPM content (9.635 g/L) of the Yellow River is the highest among the world large rivers. Compared with the Yangtze River, the Yellow River SPM has much lower clay content and significantly higher contents of clastic silicates and carbonates. In comparison to the upper crust rocks, the Yellow River SPM contains less SiO2, CaO, K2O and Na2O, but more TFe2O3, Co, Ni, Cu, Zn, Pb and Cd. The abnormal high Cd contents found in some sample may be related to local industrial activity. The REE contents and distribution pattern of the Yellow River SPM are very close to the average value of the global shale. The average δ30SiSPM in the Yellow River (?0.11‰) is slightly higher than the average value (?0.22‰) of the Yangtze River SPM. The major factors controlling the δ30SiSPM of the Yellow River are the soil supply, the isotopic composition of the soil and the climate conditions. The TDS in the Yellow River are the highest among those of world large rivers. Fair correlations are observed among Cl?, Na+, K+, and Mg2+ contents of the Yellow River water, indicating the effect of evaporation. The Ca2+ and Sr2+ concentrations show good correlation to the SO42? concentration rather than HCO3? concentration, reflecting its origin from evaporates. The NO3? contents are affected by farmland fertilization. The Cu, Zn and Cd contents in dissolved load of the Yellow River water are all higher than those of average world large rivers, reflecting the effect of human activity. The dissolved load in the Yellow River water generally shows a REE distribution pattern parallel to those for the Yangtze River and the Xijiang River. The δ30Si values of the dissolved silicon vary in a range from 0.4‰ to 2.9‰, averaging 1.34‰. The major processes controlling the DSi and δ30SiDiss of the Yellow River water are the weathering process of silicate rocks, growth of phytolith in plants, evaporation, dissolution of phytolith in soil, growth of fresh water diatom, adsorption and desorption of aqueous monosilicic acid on iron oxide and human activities. The average δ30SiDiss value of the Yellow River is significantly lower than that of the Nile River, Yangtze River and Siberia rivers, but higher than those of other rivers, reflecting their differences in chemical weathering and biological activity. The δ34SSO4 values of the Yellow River water range from ?3.8‰ to 14.1‰, averaging 7.97‰. There is some correlation between SO42? content and δ34SSO4. The factors controlling the δ34SSO4 of the Yellow River water are the SO4 in the meteoric water, the SO4 from gypsum or anhydrite in evaporite rocks, oxidation and dissolution of sulfides in the mineral deposits, magmatic rocks and sedimentary rocks, the sulfate reduction and precipitation process and the sulfate from fertilizer. The 87Sr/86Sr ratios of all samples range from 0.71041 to 0.71237, averaging 0.71128. The variations in the 87Sr/86Sr ratio and Sr concentration of river water are primarily caused by mixing of waters of various origins with different 87Sr/86Sr ratios and Sr contents resulting from water-rock interaction with different rock types.

    Abstract:

    The chemical and isotopic characteristics of the water and suspended particulate materials (SPM) in the Yellow River were investigated on the samples collected from 29 hydrological monitoring stations in the mainstem and several major tributaries during 2004 to 2007. The δD and δ18O values of the Yellow River water vary in large ranges from ?32‰ to ?91‰ and from ?3.1‰ to ?12.5‰, respectively. The characters of H and O isotope variations indicate that the major sources of the Yellow River water are meteoric water and snow melting water, and water cycle in the Yellow River basin is affected strongly by evaporation process and human activity. The average SPM content (9.635 g/L) of the Yellow River is the highest among the world large rivers. Compared with the Yangtze River, the Yellow River SPM has much lower clay content and significantly higher contents of clastic silicates and carbonates. In comparison to the upper crust rocks, the Yellow River SPM contains less SiO2, CaO, K2O and Na2O, but more TFe2O3, Co, Ni, Cu, Zn, Pb and Cd. The abnormal high Cd contents found in some sample may be related to local industrial activity. The REE contents and distribution pattern of the Yellow River SPM are very close to the average value of the global shale. The average δ30SiSPM in the Yellow River (?0.11‰) is slightly higher than the average value (?0.22‰) of the Yangtze River SPM. The major factors controlling the δ30SiSPM of the Yellow River are the soil supply, the isotopic composition of the soil and the climate conditions. The TDS in the Yellow River are the highest among those of world large rivers. Fair correlations are observed among Cl?, Na+, K+, and Mg2+ contents of the Yellow River water, indicating the effect of evaporation. The Ca2+ and Sr2+ concentrations show good correlation to the SO42? concentration rather than HCO3? concentration, reflecting its origin from evaporates. The NO3? contents are affected by farmland fertilization. The Cu, Zn and Cd contents in dissolved load of the Yellow River water are all higher than those of average world large rivers, reflecting the effect of human activity. The dissolved load in the Yellow River water generally shows a REE distribution pattern parallel to those for the Yangtze River and the Xijiang River. The δ30Si values of the dissolved silicon vary in a range from 0.4‰ to 2.9‰, averaging 1.34‰. The major processes controlling the DSi and δ30SiDiss of the Yellow River water are the weathering process of silicate rocks, growth of phytolith in plants, evaporation, dissolution of phytolith in soil, growth of fresh water diatom, adsorption and desorption of aqueous monosilicic acid on iron oxide and human activities. The average δ30SiDiss value of the Yellow River is significantly lower than that of the Nile River, Yangtze River and Siberia rivers, but higher than those of other rivers, reflecting their differences in chemical weathering and biological activity. The δ34SSO4 values of the Yellow River water range from ?3.8‰ to 14.1‰, averaging 7.97‰. There is some correlation between SO42? content and δ34SSO4. The factors controlling the δ34SSO4 of the Yellow River water are the SO4 in the meteoric water, the SO4 from gypsum or anhydrite in evaporite rocks, oxidation and dissolution of sulfides in the mineral deposits, magmatic rocks and sedimentary rocks, the sulfate reduction and precipitation process and the sulfate from fertilizer. The 87Sr/86Sr ratios of all samples range from 0.71041 to 0.71237, averaging 0.71128. The variations in the 87Sr/86Sr ratio and Sr concentration of river water are primarily caused by mixing of waters of various origins with different 87Sr/86Sr ratios and Sr contents resulting from water-rock interaction with different rock types.

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DING Tiping, GAO Jianfei, TIAN Shihong, WANG Huaibai, LI Ming, WANG Chengyu, LUO Xurong, HANG Dan.2016. Chemical and Isotopic Characters of the Water and Suspended Particulate Materials in the Yellow River and Their Geological and Environmental Implications[J]. ACTA GEOLOGICA SINICA(English edition),90(1):285~351

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  • 收稿日期:2015-05-29
  • 最后修改日期:2015-10-10
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  • 在线发布日期: 2016-02-07
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