磁铁矿纳米颗粒高效去除秘鲁坦博河的水溶液和天然水中的砷

IF 3 4区 环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL Journal of Environmental Health Science and Engineering Pub Date : 2022-09-14 DOI:10.1007/s40201-022-00825-y
M. Huanca Ccamerccoa,  N. L. Tapia Falcon, L. León Félix, D. G. Pacheco-Salazar, F. F. H. Aragón, J. A. H. Coaquira, Jéremie Garnier, C. Vera-Gonzales
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引用次数: 0

摘要

水是地球上必不可少的化合物,是生命所必需的。在许多情况下,砷等剧毒污染物的存在是地球人口面临的最大问题之一。用磁铁矿(Fe3O4)纳米颗粒(NPs)处理受污染的水可以在除砷方面发挥关键作用。在本报告中,我们演示了使用共沉淀法合成的磁铁矿NPs从秘鲁河流(秘鲁阿雷基帕的坦博河)的水溶液和天然水中去除砷。Fe3O4 NPs的XRD数据分析显示,磁铁矿形成立方尖晶石相,平均晶粒尺寸为~ 13 nm,与TEM图像分析的物理尺寸一致。磁性结果表明,我们的NPs表现出超顺磁性行为,磁矩的热松弛是由强粒子-粒子相互作用介导的。FTIR吸收波段显示砷酸盐阴离子与Fe-O和Fe-OH基团通过复杂的机制相互作用。实验结果表明,前10 min对砷的吸附速度较快;而在60 min内达到平衡,砷的去除效率为97%。吸附动力学用拟二级动力学方程很好地模拟了,表明吸附过程与化学吸附模型有关。根据Langmuir模型,在pH = 2.5时砷的最大吸附量为81.04 mg·g−1,这说明吸附过程是单层的,但我们的研究结果表明,在单层饱和后可以产生多层吸附,这与Freundlich模型一致。Sips模型证实了这一发现,该模型与实验数据具有良好的相关性。使用取自Tambo河的天然水进行的测试表明,砷浓度从356 μ g L - 1显著降低至7.38 μ g L - 1,后者低于世界卫生组织规定的限值(10 μ g L - 1),这表明磁铁矿NPs具有很大的除砷潜力。
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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High efficiency of magnetite nanoparticles for the arsenic removal from an aqueous solution and natural water taken from Tambo River in Peru

Water is an essential compound on earth and necessary for life. The presence of highly toxic contaminants such as arsenic and others, in many cases, represents one of the biggest problems facing the earth´s population. Treatment of contaminated water with magnetite (Fe3O4) nanoparticles (NPs) can play a crucial role in arsenic removal. In this report, we demonstrate arsenic removal from an aqueous solution and natural water taken from the Peruvian river (Tambo River in Arequipa, Peru) using magnetite NPs synthesized by the coprecipitation method. XRD data analysis of Fe3O4 NPs revealed the formation of the cubic-spinel phase of magnetite with an average crystallite size of ~ 13 nm, which is found in good agreement with the physical size assessed from TEM image analysis. Magnetic results evidence that our NPs show a superparamagnetic-like behavior with a thermal relaxation of magnetic moments mediated by strong particle-particle interactions. FTIR absorption band shows the interactions between arsenate anions and Fe-O and Fe-OH groups through a complex mechanism. The experimental results showed that arsenic adsorption is fast during the first 10 min; while the equilibrium is reached within 60 min, providing an arsenic removal efficiency of ~ 97%. Adsorption kinetics is well modeled using the pseudo-second-order kinetic equation, suggesting that the adsorption process is related to the chemisorption model. According to Langmuir’s model, the maximum arsenic adsorption capacity of 81.04 mg·g− 1 at pH = 2.5 was estimated, which describes the adsorption process as being monolayer, However, our results suggest that multilayer adsorption can be produced after monolayer saturation in agreement with the Freundlich model. This finding was corroborated by the Sips model, which showed a good correlation to the experimental data. Tests using natural water taken from Tambo River indicate a significant reduction of arsenic concentration from 356 µg L− 1 to 7.38 µg L− 1, the latter is below the limit imposed by World Health Organization (10 µg L− 1), suggesting that magnetite NPs show great potential for the arsenic removal.

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来源期刊
Journal of Environmental Health Science and Engineering
Journal of Environmental Health Science and Engineering ENGINEERING, ENVIRONMENTAL-ENVIRONMENTAL SCIENCES
CiteScore
7.50
自引率
2.90%
发文量
81
期刊介绍: Journal of Environmental Health Science & Engineering is a peer-reviewed journal presenting timely research on all aspects of environmental health science, engineering and management. A broad outline of the journal''s scope includes: -Water pollution and treatment -Wastewater treatment and reuse -Air control -Soil remediation -Noise and radiation control -Environmental biotechnology and nanotechnology -Food safety and hygiene
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