用于废水处理的生物炭:解决污染物问题,提高可持续性:挑战与解决方案

IF 5.4 Q2 ENGINEERING, ENVIRONMENTAL
Mohammed Ali Alshehri , Arivalagan Pugazhendhi
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引用次数: 0

摘要

近年来,生物炭因其在处理和去除生活、市政和工业废水中污染物方面的潜在用途而备受关注。在固定过滤塔(BFC)中使用生物炭时,生物炭可以有效地固定、过滤和回收污染物,并具有很高的处理效率。平均而言,化学需氧量的去除率为 80%,氮氨营养物的去除率为 71%,磷磷酸盐的去除率为 57%,病原体的平均减少量为 2.4 log10 单位。这些结果因生物炭的表面积、热解条件以及水力负荷和停留时间等操作参数而异。生物炭利用吸附、离子交换和生物降解机制解决了传统废水处理的局限性。工程生物炭具有较大的表面积和功能化表面,因此在处理各种污染物(包括重金属、营养物质和新出现的污染物,如抗生素耐药菌)方面特别有效。随着全球人口和工业活动的增加,对可持续废水处理技术的需求日益迫切。生物炭可满足这一需求,并可作为一种废物价值化工具,为生物能源生产、土壤改良和其他应用做出贡献。本综述侧重于通过应对物理降解等挑战,提高生物炭在实际应用中的性能和耐久性。本综述还提出了提高生物炭性能和再利用潜力的策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Biochar for wastewater treatment: Addressing contaminants and enhancing sustainability: Challenges and solutions

Biochar for wastewater treatment: Addressing contaminants and enhancing sustainability: Challenges and solutions
In recent years, biochar has gained interest for its potential use in treating and removing contaminants from domestic, municipal, and industrial wastewater. When applied in fixed filter columns (BFCs), biochar can effectively immobilize, filter, and recover contaminants with high treatment efficiency. On average, COD removal is 80 %, nutrient removal is 71 % for nitrogen-ammonium and 57 % for phosphorus-phosphate, and pathogen reduction averages 2.4 log10 units. These results vary depending on factors such as the biochar's surface area, the conditions under which it was pyrolyzed, and operational parameters like hydraulic loading and retention time. Biochar addresses limitations in traditional wastewater treatment by leveraging adsorption, ion exchange, and biological degradation mechanisms. The larger surface area and functionalized surface of engineered biochar make it particularly effective in treating diverse pollutants, including heavy metals, nutrients, and emerging contaminants, such as antibiotic-resistant bacteria. As the global population and industrial activities increase, there is a pressing need for sustainable wastewater treatment technologies. Biochar addresses this need and serves as a waste valorization tool, contributing to bioenergy production, soil improvement, and other applications. The present review focuses on improving biochar's performance and durability in real-world applications by addressing challenges like physical degradation. It also proposes strategies to enhance biochar's properties and reuse potential.
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来源期刊
Journal of hazardous materials advances
Journal of hazardous materials advances Environmental Engineering
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