Adsorption methods for arsenic removal in water bodies: a critical evaluation of effectiveness and limitations

Frontiers in Water Pub Date : 2024-02-07 DOI:10.3389/frwa.2024.1301648

Amin Mojiri, Elham Razmi, Bahareh KarimiDermani, S. Rezania, Norhafezah Kasmuri, Mohammadtaghi Vakili, Hossein Farraji

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Abstract

The presence of arsenic in water bodies poses a significant risk to both human health and the environment. Arsenic (As) contamination in water sources is a global environmental concern caused by both natural processes and human activities. Due to its toxic and persistent nature, arsenic has detrimental effects on ecosystems and human wellbeing. This study aimed to elucidate the mechanisms behind arsenic accumulation in water bodies. In aquatic environments, arsenic concentrations in drinking water have been reported as high as 1,320 μg/L (Nicaragua), while groundwater levels exceeded 5,000 μg/L (Thailand), and wastewater contained up to 134,000 μg/L (landfill leachate in Brazil). Furthermore, bioaccumulation of arsenic (μg/g) in fish species ranges from 0.4 (catfish in the Paraná River Delta, Brazil) to 362 (Pteromylaeus bovinus, Northern Adriatic Sea). Recent research has predominantly focused on removing arsenic from aqueous solutions through adsorption methods. Notably, nanoparticle adsorbents and graphene-based adsorbents demonstrate a high capacity for arsenic removal from water bodies.

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吸附法去除水体中的砷：对有效性和局限性的严格评估

水体中的砷对人类健康和环境都构成了重大风险。水源中的砷（As）污染是由自然过程和人类活动引起的全球环境问题。由于砷具有毒性和持久性，它对生态系统和人类福祉都有不利影响。本研究旨在阐明砷在水体中累积的机制。据报道，在水生环境中，饮用水中的砷浓度高达 1,320 μg/L（尼加拉瓜），地下水中的砷浓度超过 5,000 μg/L（泰国），废水中的砷浓度高达 134,000 μg/L（巴西垃圾填埋场沥滤液）。此外，砷在鱼类物种中的生物累积量（微克/克）从 0.4（巴西巴拉那河三角洲的鲶鱼）到 362（北亚得里亚海的 Pteromylaeus bovinus）不等。最近的研究主要集中在通过吸附方法去除水溶液中的砷。值得注意的是，纳米颗粒吸附剂和基于石墨烯的吸附剂显示出很强的从水体中去除砷的能力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Frontiers in Water

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