Highly Efficient NO Conversion on Layered Photocatalysts: Surface Active Site Regulation and Molecule Activation

IF 2 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Aerosol Science and Engineering Pub Date : 2024-10-24 DOI:10.1007/s41810-024-00263-3

Yizhou Zhi, Yanfeng Lu, Yu Huang, Xianghan Li, Shun Cheng Lee

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Abstract

Nitrogen oxides (NOx) in the atmosphere are significant precursors to the formation of fine particulate matter (PM_2.5) and ozone. Effectively reducing the concentration of NOx in the ambient air is crucial for the air pollution control Photocatalytic purification technology harnesses solar energy, operates under mild reaction conditions, and can convert low concentrations NO into nitrates, providing metabolic nitrogen for plant growth. From the perspectives of geochemical cycling and environmental pollution control, it is one of the most promising technologies for the purification of environmental atmospheric pollution. However, traditional catalysts face limitations in practical applications, such as low molecular activation rates, uncontrollable redox capabilities, and poor performance stability. materials. Emphasizing the critical role of active surface site control and molecular This review provides a comprehensive analysis of the advancements in photocatalytic NOx removal using ultrathin layered activation, the study explores various strategies, including defect engineering, crystal facet regulation, element doping, single-atom catalysts, and plasmon coupling, to enhance photocatalytic efficiency and selectivity. Key findings demonstrate that these advanced materials significantly improve NO adsorption, activation, and conversion, leading to higher photocatalytic performance. Despite these advancements, challenges such as the precise control of surface electronic structures, stability of active sites, scalability, and economic feasibility remain. The review highlights the need for further research to address these challenges and optimize photocatalytic technologies for large-scale applications. This work contributes to the field by offering insights into the mechanisms and potential of layered photocatalysts for sustainable and efficient air purification.

Graphical Abstract

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层状光催化剂的高效NO转化：表面活性位点调控和分子活化

大气中的氮氧化物（NOx）是形成细颗粒物（PM2.5）和臭氧的重要前体。光催化净化技术利用太阳能，在温和的反应条件下运行，可以将低浓度的NO转化为硝酸盐，为植物生长提供代谢氮。从地球化学循环和环境污染控制的角度来看，它是净化环境大气污染最有前途的技术之一。然而，传统催化剂在实际应用中存在分子活化率低、氧化还原能力不可控、性能稳定性差等局限性。材料。本文综述了超薄层活化技术在光催化脱除NOx方面的研究进展，探讨了包括缺陷工程、晶面调控、元素掺杂、单原子催化剂和等离子体耦合等多种策略，以提高光催化效率和选择性。关键发现表明，这些先进材料显著改善了NO的吸附、活化和转化，从而提高了光催化性能。尽管取得了这些进步，但诸如表面电子结构的精确控制、活性位点的稳定性、可扩展性和经济可行性等挑战仍然存在。该综述强调需要进一步研究以解决这些挑战并优化大规模应用的光催化技术。这项工作通过提供对层状光催化剂可持续和高效空气净化的机制和潜力的见解，为该领域做出了贡献。图形抽象

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来源期刊

Aerosol Science and Engineering Environmental Science-Pollution

CiteScore

3.00

自引率

7.10%

发文量

期刊介绍： ASE is an international journal that publishes high-quality papers, communications, and discussion that advance aerosol science and engineering. Acceptable article forms include original research papers, review articles, letters, commentaries, news and views, research highlights, editorials, correspondence, and new-direction columns. ASE emphasizes the application of aerosol technology to both environmental and technical issues, and it provides a platform not only for basic research but also for industrial interests. We encourage scientists and researchers to submit papers that will advance our knowledge of aerosols and highlight new approaches for aerosol studies and new technologies for pollution control. ASE promotes cutting-edge studies of aerosol science and state-of-art instrumentation, but it is not limited to academic topics and instead aims to bridge the gap between basic science and industrial applications. ASE accepts papers covering a broad range of aerosol-related topics, including aerosol physical and chemical properties, composition, formation, transport and deposition, numerical simulation of air pollution incidents, chemical processes in the atmosphere, aerosol control technologies and industrial applications. In addition, ASE welcomes papers involving new and advanced methods and technologies that focus on aerosol pollution, sampling and analysis, including the invention and development of instrumentation, nanoparticle formation, nano technology, indoor and outdoor air quality monitoring, air pollution control, and air pollution remediation and feasibility assessments.