从生物质废物到生物气凝胶--废水补救的另一种可持续方法。

IF 7.7 1区 化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY
A K Priya, Huda M Alghamdi, V Kavinkumar, Khalid Z Elwakeel, Ahmed M Elgarahy
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引用次数: 0

摘要

城市固体废物的产生量预计将从 2023 年的 21 亿吨增加到 2050 年的 38 亿吨。2020 年,全球管理这些废物的直接成本约为 2 520 亿美元。如果考虑到额外的隐性成本,如由于废物处理不当造成的污染、对健康的不利影响和气候变化,总成本将上升到 3 610 亿美元。如果不大力改进废物管理方法,到 2050 年,这一数字将翻一番,估计每年将达到 6 403 亿美元。在城市固体废物中,生物垃圾约占全球城市固体废物的 44%,即每年约 8.4 亿吨。生物质废物来源广泛,经济实惠,是传统处理材料的一种经济有效的替代品。将生物质废物转化为碳基材料(如生物气凝胶)是一种可持续的做法,既能减少废物,又能将其重新用于环境修复。这种方法不仅可以减少垃圾填埋量,减少分解产生的有害温室气体排放,还符合循环经济的原则。此外,这种方法还能解决水资源短缺和污染等问题,同时促进废物价值化和提高资源效率,从而支持可持续发展目标。生物气凝胶的独特性能,包括多孔性、多层结构和化学适应性,使其在修复水体中的不同水污染物方面非常有效。这篇综述文章全面探讨了基于生物气凝胶的多方面废水修复策略,如混凝和絮凝、高级氧化过程、膜过滤、催化过程、水消毒、油水分离、生物降解和吸附。此外,它还研究了不同的相互作用机制,如表面吸附、静电相互作用、范德华力、离子交换、表面沉淀、络合、孔隙填充、疏水相互作用和 π-π 堆积。此外,它还进行了综合技术经济评估,以评估其在废水处理中的可行性。通过对生物质废物进行估值,可以建立一个闭环系统,将废物转化为有价值的生物气凝胶。这种方法不仅能应对与污水污染有关的挑战,还能产生经济、环境和社会效益。综述最终强调了生物气凝胶在废水处理方面的变革潜力,强调了其在支持长期环境目标和推进资源循环原则方面的关键作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bioaerogels from biomass waste: An alternative sustainable approach for wastewater treatment.

The generation of municipal solid waste is projected to increase from 2.1 billion tonnes in 2023 to 3.8 billion tonnes by 2050. In 2020, the direct global cost of managing this waste was approximately USD 252 billion. When considering additional hidden costs-such as those arising from pollution, adverse health effects, and climate change due to inadequate waste disposal-the total cost escalates to USD 361 billion. Without significant improvements in waste management practices, this figure could nearly double by 2050, reaching an estimated USD 640.3 billion annually. Among municipal solid waste, biowaste accounts for roughly 44 % of the global municipal solid waste, translating to about 840 million tonnes annually. They are widely accessible and economical, offering a cost-effective alternative to traditional treatment materials. Transforming biomass waste into carbon-based materials (e.g., bioaerogels) is a sustainable practice that reduces waste and repurposes it for environmental remediation. This approach not only decreases the volume of waste directed to landfills and mitigates harmful greenhouse gas emissions from decomposition but also aligns with the principles of a circular economy. Furthermore, it supports sustainable development goals by addressing issues such as water scarcity and pollution while promoting waste valorization and resource efficiency. The unique properties of bioaerogels-including their porosity, multi-layered structure, and chemical adaptability-make them highly effective for the remediation of different water pollutants from aquatic bodies. This review article comprehensively delves into multifaceted wastewater remediation strategies -based bioaerogels such as coagulation and flocculation, advanced oxidation processes, membrane filtration, catalytic processes, water disinfection, Oil-water separation, biodegradation, and adsorption. Additionally, it examines different mechanisms of interaction such as surface adsorption, electrostatic interaction, van der Waals forces, ion exchange, surface precipitation, complexation, pore-filling, hydrophobic interactions, and π-π stacking. Moreover, it conducts an integrated techno-economic evaluation to assess their feasibility in wastewater treatment. By valorizing biomass waste, a closed-loop system can be established, where waste is transformed into valuable bioaerogels. This approach not only addresses challenges related to effluent pollution but also generates economic, environmental, and social benefits. Ultimately, the review underscores the transformative potential of bioaerogels in wastewater treatment, emphasizing their crucial role in supporting long-term environmental goals and advancing the principles of resource circularity.

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来源期刊
International Journal of Biological Macromolecules
International Journal of Biological Macromolecules 生物-生化与分子生物学
CiteScore
13.70
自引率
9.80%
发文量
2728
审稿时长
64 days
期刊介绍: The International Journal of Biological Macromolecules is a well-established international journal dedicated to research on the chemical and biological aspects of natural macromolecules. Focusing on proteins, macromolecular carbohydrates, glycoproteins, proteoglycans, lignins, biological poly-acids, and nucleic acids, the journal presents the latest findings in molecular structure, properties, biological activities, interactions, modifications, and functional properties. Papers must offer new and novel insights, encompassing related model systems, structural conformational studies, theoretical developments, and analytical techniques. Each paper is required to primarily focus on at least one named biological macromolecule, reflected in the title, abstract, and text.
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