Highly efficient removal of aqueous phosphate via iron-manganese fabricated biochar: Performance and mechanism.

Chemosphere Pub Date : 2024-09-01 Epub Date: 2024-08-29 DOI:10.1016/j.chemosphere.2024.143207
Jingzi Beiyuan, Xinyi Wu, Bo Ruan, Zeyu Chen, Juan Liu, Jin Wang, Jiangshan Li, Weicheng Xu, Wenbing Yuan, Hailong Wang
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Abstract

Biochar (BC) has emerged as a potential solution to phosphate removal from wastewater primarily resulting from global overuse of fertilizers. Further modification by embedment of iron (Fe)-manganese (Mn) oxides on BC can enhance phosphate removal; however, the modification method serves as a vital factor underlying distinctive removal performances and mechanisms, which have yet been systematically examined. Herein, two Fe-Mn modified BC, Fe/MnBC (comprised of Fe3O4 and MnO2) and Fe-MnBC (comprised of MnFe2O4), were comprehensively investigated for gaining insights into the unsolved perspectives. The results indicated that Fe-MnBC exhibited a markedly greater maximum phosphate adsorption capacity of 135.88 mg g-1 than that of Fe/MnBC with 17.93 mg g-1. The comparative results based on microstructure and spectroscopic analyses suggested that different Fe and Mn oxides were successfully loaded, which played a distinctive role in phosphate removal. Further characterizations unveiled that the key mechanisms for phosphate removal by Fe/MnBC are inner-sphere complexation and precipitation, while electrostatic interaction and outer-sphere complexation are the dominant mechanisms underlying the notable performance of Fe-MnBC. The delicately designed Fe-MnBC with special structure and property also enabled a superior regeneration capacity, which presented a promisingly high phosphate removal efficacy of over 81.34% after five cycles. These results enhance comprehension regarding the impact of biochar modification techniques on phosphate removal, offering positive indications for the remediation of excessive phosphate and other pollutant-containing water through feasible design and green chemicals.

通过铁锰生物炭高效去除水体中的磷酸盐:性能和机理。
生物炭(BC)已成为去除废水中磷酸盐的潜在解决方案,主要原因是全球过度使用化肥。通过在生物炭上嵌入铁(Fe)-锰(Mn)氧化物进行进一步改性,可以提高磷酸盐的去除率;然而,改性方法是影响不同去除性能和机制的重要因素,目前尚未对其进行系统研究。本文全面研究了两种铁-锰改性萃取物,即铁/锰萃取物(由 Fe3O4 和 MnO2 组成)和铁-锰萃取物(由 MnFe2O4 组成),以深入了解尚未解决的问题。结果表明,Fe-MnBC 的最大磷酸盐吸附容量为 135.88 mg g-1,明显高于 Fe/MnBC 的 17.93 mg g-1。基于微观结构和光谱分析的比较结果表明,不同的铁和锰氧化物被成功负载,在去除磷酸盐方面发挥了独特的作用。进一步的表征揭示了Fe/MnBC去除磷酸盐的关键机制是内球络合和沉淀,而静电作用和外球络合是Fe-MnBC显著性能的主导机制。精心设计的铁锰电池具有特殊的结构和性能,因此再生能力极强,经过五个循环后,磷酸盐去除率达到 81.34% 以上,令人鼓舞。这些结果加深了人们对生物炭改性技术对磷酸盐去除的影响的理解,为通过可行的设计和绿色化学品修复过量磷酸盐和其他含污染物的水提供了积极的参考。
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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