Zn Isotope Tracing Unveils Primary Anthropogenic Zn Sources in Glacial Cryoconite of the High Asian Mountains

IF 3.8 2区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES Journal of Geophysical Research: Atmospheres Pub Date : 2024-10-09 DOI:10.1029/2024JD041467
Rui Wu, Zhiwen Dong, Yan Yan, Eric Parteli, Ting Wei, Fangzhou Li, Xiaoyu Jiao, Yaping Shao, Xiang Qin
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Abstract

Zinc (Zn) exerts a significant influence on the global environment, terrestrial ecosystems, and human health. The application of Zn isotopes (δ66Zn) has been suggested as a potent tool for tracing environmental contamination. However, studies focusing on Zn isotope tracing within the cryosphere areas are notably limited. Here we present the first data set on Zn isotopes in glacial cryoconite, based on observations over a large regional scale in High Asian Mountains (including Tibetan Plateau (TP) and its surroundings of western China). The results showed that glacial cryoconite had a general heavy Zn isotopic signature in various TP locations, with δ66Zn values ranging from −0.22‰ to +0.87‰. Employing the MixSIAR model, the overall Zn contribution source to the cryoconite was mineral dust (36%) > coal burning (33%) > non-exhaust traffic emissions (22%) > industrial smelting (10%). We ascertained that anthropogenic sources account for the primary contribution (about 60%–73%) of Zn inputs in all glacial locations, with coal burning emerging as the foremost anthropogenic contributor (mean 33%). Anthropogenic Zn in various TP locations was primarily derived from Zn emissions resulting from coal combustion, though it is also predominantly influenced by industrial smelting source in cryoconite of the Tianshan Mountains. Our results aligned with coal combustion data from the energy inventory of western China, suggesting that regional coal burning likely represents the foremost source of atmospheric Zn pollutant emission and deposition in the High Asia mountain glaciers.

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锌同位素追踪揭示了亚洲高山冰川冻土中主要的人为锌来源
锌(Zn)对全球环境、陆地生态系统和人类健康有着重大影响。锌同位素(δ66Zn)被认为是追踪环境污染的有效工具。然而,针对冰冻圈内锌同位素追踪的研究却非常有限。在此,我们基于对亚洲高山(包括青藏高原及其中国西部周边地区)大区域尺度的观测,首次提出了冰川冰晶石中锌同位素的数据集。结果表明,在青藏高原的不同地点,冰川冻土的锌同位素特征普遍较重,δ66Zn值在-0.22‰到+0.87‰之间。利用 MixSIAR 模型,冰晶石的总体锌贡献源为矿尘(36%);燃煤(33%);非废气交通排放(22%);工业冶炼(10%)。我们确定,人为来源是所有冰川地点锌输入量的主要来源(约占 60%-73% ),其中燃煤是最主要的人为来源(平均占 33%)。各 TP 地点的人为锌主要来自燃煤产生的锌排放,但也主要受天山冰川工业冶炼源的影响。我们的研究结果与中国西部能源清单中的燃煤数据一致,表明区域燃煤可能是亚洲高山冰川大气中锌污染物排放和沉积的主要来源。
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来源期刊
Journal of Geophysical Research: Atmospheres
Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics
CiteScore
7.30
自引率
11.40%
发文量
684
期刊介绍: JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.
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