Novel Isotopic Evidence Unveils Greater Contributions of Waste Incineration to PM2.5-Bound Antimony in Two Mega-Cities

IF 3.4 2区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Journal of Geophysical Research: Atmospheres Pub Date : 2025-02-19 DOI:10.1029/2024JD042748

Chao Zhang, Guangyi Sun, Yunjie Wu, Xinyu Li, Dong-Xing Guan, Jinling Liu, Lena Q. Ma, Xinbin Feng

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Abstract

PM_2.5-bound antimony (Sb) may threaten human health and sustainable development, necessitating accurate source identification for its effective control. This study pioneered the application of Sb isotope signatures to trace PM_2.5-bound Sb sources, presenting the first isotopic fingerprints of Sb in urban PM_2.5. We selected two mega-cities with contrasting profiles: more developed Wuhan in central and less developed Guiyang in southwest China. Urban PM_2.5 in both cities exhibited an ε¹²³Sb value of 1.84 ± 0.79‱, with a distinct seasonal pattern, that is, heavier isotopes in spring/winter and lighter in summer/autumn. Isotopic source apportionment revealed waste incineration as the predominant anthropogenic Sb source in PM_2.5 for both cites at 34.0–39.1%, despite their massive economic and industrial differences. Brake wear emerged as the second major anthropogenic source, especially in Wuhan, where vehicle ownership is greater, accounting for 21.2%. Complementary analyses using enrichment factor, elemental ratios, positive matrix factorization modeling, and backward trajectory analysis corroborated the isotopic findings. This study offers a novel isotopic approach to identify PM_2.5-bound Sb sources, unveiling waste incineration and brake wear as major anthropogenic contributors from a new isotopic perspective.

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新的同位素证据揭示了两个大城市垃圾焚烧对pm2.5结合锑的更大贡献

pm2.5结合的锑可能威胁人类健康和可持续发展，需要准确的来源识别才能有效控制。本研究率先应用Sb同位素特征来追踪PM2.5结合的Sb源，首次提出了城市PM2.5中Sb的同位素指纹图谱。我们选择了两个具有鲜明对比的特大城市：中部较发达的武汉和西南欠发达的贵阳。两市城市PM2.5的ε123Sb值均为1.84±0.79‰，且具有明显的季节特征，春、冬季同位素较重，夏、秋季同位素较轻。同位素源分析显示，垃圾焚烧是两个城市PM2.5中主要的人为Sb源，占34.0 ~ 39.1%，尽管它们的经济和工业存在巨大差异。刹车磨损成为第二大人为来源，特别是在车辆保有量较大的武汉，占21.2%。利用富集因子、元素比、正矩阵分解模型和反向轨迹分析进行的补充分析证实了同位素的发现。这项研究提供了一种新的同位素方法来识别pm2.5结合的Sb源，从新的同位素角度揭示了垃圾焚烧和刹车磨损是主要的人为贡献者。

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来源期刊

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.