Tasrina Rabia Choudhury , Md. Sajjad Hossain Sajib , Sheikh Fahim Faysal Sowrav , Shahidur R. Khan , M. Nur E. Alam , Md. Nurul Amin
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引用次数: 0
摘要
砷(As)元素具有不同的价态,严重危害生态质量和人类健康。在这项研究中,使用甘蔗渣-锰-铝(一种从甘蔗渣中提取的浸渍有锰和铝的生物炭)可以高效去除水基溶液中的砷(III)。与生物炭本身相比,甘蔗渣-锰-铝复合材料对 As (III) 的去除效率更高。在 As (III) 的初始浓度为 400 μg/L、初始 pH 值为 2-2.5 和吸附剂用量为 0.625 g/L 的条件下,65 分钟内就能去除约 89.53% 的 As (III)。甘蔗渣-锰-铝复合材料的吸附潜能最大值为 54.945 mg/g,优于大多数廉价合成的金属浸渍生物炭。各种表征技术的研究结果表明,甘蔗渣-锰-铝复合材料中的-OH 自由基对 As (III) 的去除起了主要作用,其中氧化和络合是主要机制。由于催化效率高,这种低成本生产的金属涂层生物炭可以轻松有效地从水溶液中分离 As (III)。此外,这项研究还重点关注了甘蔗渣-锰-铝吸附剂在处理地下水和废水方面的巨大潜力。
Nanostructured bi-metallic biochar: An innovative approach for arsenic (III) removal from contaminated water
Possessing variable valence states, the element Arsenic (As) is intimidating the quality of the ecology and human health severely. In this study, eliminating As (III) from water-based solutions with great efficiency was done using Bagasse-Mn-Al, a sugarcane bagasse-derived biochar impregnated with Mn and Al. The Bagasse-Mn-Al composite yielded higher removal efficiency towards As (III) than the biochar itself. About 89.53 % of As (III) was removed within 65 min maintaining the very first concentration of As (III) at 400 μg/L, initial pH at 2–2.5, and adsorbent dosage at 0.625 g/L. The Bagasse-Mn-Al composite showed an adsorption potential maximum of 54.945 mg/g which is superior to most of the cheaply synthesized metal-impregnated biochar reported. Results from a variety of characterization techniques indicated that the •OH free radical in the Bagasse-Mn-Al composite mainly contributed to the removal of As (III) where oxidation and complexation were the major mechanisms. With high catalytic efficiency, this cost effectively produced metal-coated biochar showed easy and effective separation of As (III) from aqueous solution. Further, this study focuses on the high potential of Bagasse-Mn-Al adsorbent in the treatment of both ground and wastewater.
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