Li Shehong, Wang Mingguo, Yang Qiang, Wang Hui, Zhu Jianming, Zheng Baoshan, Zheng Yan
State Key Lab of Environmental Geochemistry, Institute of Geochemistry, Chinese Academy of Sciences, Guiyang 550002, China ; School of Earth and Environmental Sciences, Queens College, City University of New York, Flushing, NY 11367, USA.
State Key Lab of Environmental Geochemistry, Institute of Geochemistry, Chinese Academy of Sciences, Guiyang 550002, China.
J Geochem Explor. 2013 Dec 1;135. doi: 10.1016/j.gexplo.2012.08.020.
Groundwater in sedimentary deposits in China, Southern, and Southeast Asia down gradient from the Tibetan plateau contain elevated As concentrations on a regional scale. To ascertain the possibility of source region As enrichment, samples of water (n=86), stream sediment (n=77) and soil (n=73) were collected from the Singe Tsangpo (upstream of the Indus River), Yarlung Tsangpo (upstream of the Brahmaputra River) and other drainage basins in Tibet in June of 2008. The average arsenic concentration in stream waters, sediments and soils was 58±70 μg/L (n=39, range 2-252 μg/L), 42±40 mg/kg (n=37, range 12-227 mg/kg), and 44±27mg/kg (n=28, range 12-84 mg/kg) respectively for the Singe Tsangpo and was 11±17 μg/L (n=30, range 2-83 μg/L), 28±11 mg/kg (n=28, range 2-61 mg/kg), and 30±34 mg/kg (n=21, range 6-173 mg/kg) respectively for the Yarlung Tsangpo. A dug well contained 195 μg/L of As. In addition to elevated As levels in surface and shallow groundwater of Tibet, hot spring and alkaline salt lake waters displayed very high As levels, reaching a maximum value of 5,985 μg/L and 10,626 μg/L As, respectively. The positive correlation between [As] and [Na]+[K] in stream waters indicates that these surface water arsenic enrichments are linked to the hot springs and/or salt lakes. Further, 24% of As in stream sediment is reductively leachable, with bulk As displaying a positive correlation with stream water As, suggesting sorption from stream water. In contrast, the fraction of reductively leachable As is negligible for soils and several rock samples, suggesting that As in them are associated with unweathered minerals. Whether the pronounced As anomaly found in Tibet affects the sedimentary As content in deltas downstream or not requires further study.
在中国、南亚和东南亚青藏高原下游的沉积矿床中的地下水,在区域尺度上含有升高的砷浓度。为了确定源区砷富集的可能性,2008年6月从西藏的狮泉河(印度河上游)、雅鲁藏布江(雅鲁藏布江上游)和其他流域采集了水样(n = 86)、河流沉积物(n = 77)和土壤样本(n = 73)。狮泉河的河水、沉积物和土壤中的平均砷浓度分别为58±70μg/L(n = 39,范围2 - 252μg/L)、42±40mg/kg(n = 37,范围12 - 227mg/kg)和44±27mg/kg(n = 28,范围12 - 84mg/kg),雅鲁藏布江的分别为11±17μg/L(n = 30,范围2 - 83μg/L)、28±11mg/kg(n = 28,范围2 - 61mg/kg)和30±34mg/kg(n = 21,范围6 - 173mg/kg)。一口挖井中含有195μg/L的砷。除了西藏地表水和浅层地下水中的砷含量升高外,温泉和碱性盐湖水中的砷含量也非常高,分别达到最大值5985μg/L和10626μg/L的砷。河水中[As]与[Na]+[K]之间的正相关表明,这些地表水砷富集与温泉和/或盐湖有关。此外,河流沉积物中24%的砷可被还原浸出,总体砷与河水砷呈正相关,表明是从河水中吸附而来。相比之下,土壤和几个岩石样品中可被还原浸出的砷比例可以忽略不计,表明其中的砷与未风化矿物有关。西藏发现的明显砷异常是否会影响下游三角洲的沉积砷含量,还需要进一步研究。
