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印度南部半干旱地区地球化学过程对地下水化学的影响以及与氟摄入相关的健康风险。

The effects of geochemical processes on groundwater chemistry and the health risks associated with fluoride intake in a semi-arid region of South India.

作者信息

Karunanidhi D, Aravinthasamy P, Deepali M, Subramani T, Roy Priyadarsi D

机构信息

Department of Civil Engineering, Sri Shakthi Institute of Engineering and Technology (Autonomous) Coimbatore - 641062 India

Department of Applied Chemistry, Priyadarshini Institute of Engineering and Technology Nagpur - 440019 India.

出版信息

RSC Adv. 2020 Jan 29;10(8):4840-4859. doi: 10.1039/c9ra10332e. eCollection 2020 Jan 24.

DOI:10.1039/c9ra10332e
PMID:35693695
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9122570/
Abstract

This study attempts to establish the effects of subsurface geochemical processes based on the hydrogeochemical attributes of 61 well samples collected in a semi-arid region of South India. The study also provides the health risks associated with the consumption of fluoride-enriched groundwater by the rural people since groundwater is the major source of water supply in the Shanmuganadhi River basin. In this work, water-rock interaction diagrams, an entropy-weighted water quality index (EWQI), and health risk models as per the United States Environmental Protection Agency (USEPA) were prepared to understand the geochemical mechanism behind the groundwater chemistry and its role in impacting health. About 72% of these samples are of mixed Ca-Mg-Cl water type, representing a transition from freshwater to brackish water, and 36% of them have fluoride above the permissible limit (>1.5 mg l). An evaluation of the hydrogeochemical attributes suggests that silicate weathering, carbonate dissolution and reverse ion exchange mostly control the hydrochemistry of the groundwater. The EWQI characterizes about 30% of these samples as unsuitable for drinking and another 49% as of moderate quality. Human health risks were evaluated by dividing the population into seven different age groups and estimating the hazard quotient (HQ) and total hazard index (THI) from intake and dermal contact with fluoride-rich groundwater. The groundwater of this region poses a higher risk for the younger population compared to the adults. About 79% of these groundwater samples pose a health risk to 5-12 month-old infants and only 36% of the samples could be potentially hazardous for adults >23 years old. Our results suggest that the ADD pathway indicates less risk compared to the ADD estimations.

摘要

本研究试图根据在印度南部半干旱地区采集的61口井样本的水文地球化学属性,确定地下地球化学过程的影响。该研究还揭示了农村居民饮用富含氟的地下水所面临的健康风险,因为地下水是山穆加纳德希河流域的主要供水来源。在这项工作中,绘制了水 - 岩相互作用图、熵权水质指数(EWQI)以及美国环境保护局(USEPA)规定的健康风险模型,以了解地下水化学背后的地球化学机制及其对健康的影响作用。这些样本中约72%为混合的钙 - 镁 - 氯水型,代表了从淡水到微咸水的转变,其中36%的样本氟含量超过允许限值(>1.5毫克/升)。对水文地球化学属性的评估表明,硅酸盐风化、碳酸盐溶解和反向离子交换主要控制着地下水的水化学性质。EWQI将这些样本中的约30%表征为不适合饮用,另外49%为中等质量。通过将人群分为七个不同年龄组,并根据摄入和皮肤接触富含氟的地下水情况估算危害商(HQ)和总危害指数(THI),对人类健康风险进行了评估。与成年人相比,该地区的地下水对年轻人群构成的风险更高。这些地下水样本中约79%对5 - 12个月大的婴儿构成健康风险,而对于23岁以上的成年人,只有36%的样本可能具有潜在危害。我们的结果表明,与ADD估计值相比,ADD途径显示出的风险较小。

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