高温富硫化物热泉中硫代砷化物存在形态的地球化学模拟：以云南腾冲热海水热区为例

庄亚芹; 郭清海; 刘明亮; 李洁祥; 周超

doi:10.3799/dqkx.2016.513

Volume 41 Issue 9

Sep. 2016

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Zhuang Yaqin, Guo Qinghai, Liu Mingliang, Li Jiexiang, Zhou Chao, 2016. Geochemical Simulation of Thioarsenic Speciation in High-Temperature, Sulfide-Rich Hot Springs: A Case Study in the Rehai Hydrothermal Area, Tengchong, Yunnan. Earth Science, 41(9): 1499-1510. doi: 10.3799/dqkx.2016.513

Citation:

Zhuang Yaqin, Guo Qinghai, Liu Mingliang, Li Jiexiang, Zhou Chao, 2016. Geochemical Simulation of Thioarsenic Speciation in High-Temperature, Sulfide-Rich Hot Springs: A Case Study in the Rehai Hydrothermal Area, Tengchong, Yunnan. Earth Science, 41(9): 1499-1510. doi: 10.3799/dqkx.2016.513

Citation:

Zhuang Yaqin, Guo Qinghai, Liu Mingliang, Li Jiexiang, Zhou Chao, 2016. Geochemical Simulation of Thioarsenic Speciation in High-Temperature, Sulfide-Rich Hot Springs: A Case Study in the Rehai Hydrothermal Area, Tengchong, Yunnan. Earth Science, 41(9): 1499-1510. doi: 10.3799/dqkx.2016.513

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Geochemical Simulation of Thioarsenic Speciation in High-Temperature, Sulfide-Rich Hot Springs: A Case Study in the Rehai Hydrothermal Area, Tengchong, Yunnan

doi: 10.3799/dqkx.2016.513

Zhuang Yaqin^{1,2
,},
Guo Qinghai^{1,2
,
,},
Liu Mingliang^1,2,
Li Jiexiang^1,2,
Zhou Chao^1,2

1.
State Key Laboratory of Biogeology and Environmental Geology, China University of Geosciences, Wuhan 430074, China
2.
School of Environmental Studies, China University of Geosciences, Wuhan 430074, China

Received Date: 2016-01-20
Publish Date: 2016-09-15

Abstract

Abstract

The occurrence of geogenic arsenic in natural water environment is one of the significant hazards to human beings in the world. In high-temperature, sulfide-rich geothermal waters, thioarsenicals are likely the major species of arsenic. In view that there has been so far no quantitative test method for thioarsenic species in China, a hydrogeochemical code, PHREEQC, with its wateq4f.dat database being updated by the latest thermodynamic data for thioarsenicals, was used for calculating the arsenic species distribution in various types of hot springs from the Rehai hydrothermal area located in the Tengchong geothermal belt, Yunnan Province. The results show that the major species of arsenic in the Rehai hot springs is thioarsenate, arsenate and arsenite comes second, and the thioarsenite concentrations are extremely low; the descending order of thioarsenate species in terms of their average percentages is: monothioarsenate, trithioarsenate, tetrathioarsenate, and dithioarsenate. pH, Eh and total sulfide concentration are the controlling factors for the arsenic speciation in hot springs. Under acidic condition, the main species of arsenic are thioarsenate and arsenite, whereas under neutral/weak alkaline conditions, thioarsenate is predominant with arsenate being the second most important species. Comparative reducing environment and high sulfide concentration in geothermal water are favorable for the stable existence of thioarsenicals, especially trithioarsenate and tetrathioarsenate.
- hot spring,
- thioarsenic species,
- Rehai hydrothermal area,
- Tengchong geothermal belt,
- geochemistry

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References(35)

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Geochemical Simulation of Thioarsenic Speciation in High-Temperature, Sulfide-Rich Hot Springs: A Case Study in the Rehai Hydrothermal Area, Tengchong, Yunnan

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