Ali Hassanzadeh, Ebrahim Ghorbani Kalhor, Khalil Farhadi, Jafar Abolhasani
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引用次数: 0
摘要
目的 本研究旨在探讨 Ag@GO/Na2SiO3 纳米复合材料去除水溶液中 As 的功效。研究结果在优化条件下,初始 As 浓度、接触时间、pH 值和吸附剂用量分别为 32 ppm、50 分钟、6.5 克和 0.4 克。在这些条件下,预计砷的去除率为 97.6%,而实际应用的去除率为 93%。帕累托分析确定了各因素之间的重要性顺序如下:吸附剂用量;接触时间;pH 值;砷浓度。独创性/价值纳米复合材料的制备方法简单,无需先进设备,原材料便宜,具有潜在的去除 As 的能力,这是本研究的突出优势。
Arsenic adsorption from aqueous solution using graphene oxide-sodium silicate nanocomposite modified by silver nanoparticles: process modeling by response surface methodology (RSM)
Purpose
This study aims to investigate the efficacy of Ag@GO/Na2SiO3 nanocomposite in eliminating As from aqueous solutions. Employing response surface methodology, the research systematically examines the adsorption process.
Design/methodology/approach
Various experimental parameters including sample pH, contact time, As concentration and adsorbent dosage are optimized to enhance the As removal process.
Findings
Under optimized conditions, the initial As concentration, contact time, pH and adsorbent dosage are determined to be 32 ppm, 50 mins, 6.5 and 0.4 grams, respectively. While the projected removal of As stands at 97.6% under these conditions, practical application achieves a 93% removal rate. Pareto analysis identifies the order of significance among factors as follows: adsorbent dosage > contact time > pH > As concentration.
Practical implications
This study highlights the potential Ag@GO/Na2SiO3 as a promising adsorbent for efficiently removing industrial As from aqueous solutions, and it is likely to have a good sufficiency in the filtration of water and wastewater treatment plans to remove some chemical pollution, including paints and heavy metals.
Originality/value
The simplicity of the nanocomposite preparation method without the need for advanced equipment and the cheapness of the raw materials and its potential ability to remove As are the prominent advantages of this research.
期刊介绍:
The journal looks at developments in: ■Adhesives and sealants ■Curing and coatings ■Wood coatings and preservatives ■Environmentally compliant coating systems and pigments ■Inks for food packaging ■Manufacturing machinery - reactors, mills mixing and dispersing equipment, pumps ■Packaging, labeling and storage ■Plus topical features and news on materials, coatings, industry people, conferences, books and so on ■Raw materials such as pigments, solvents, resins and chemicals ■Testing equipment and procedures
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