INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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Applying Microwave-induced Catalytic Reaction to Environmental Purification: a Review |
LYU Xiujuan1, TANG Xiaolong1,2,*, YI Honghong1,2, ZHAO Shunzheng1,2, REN Chenyang1
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1 School of Energy and Environmental Engineering, University of Science and Technology Beijing, Beijing 100083, China 2 Beijing Key Laboratory of Resource-oriented Treatment of Industrial Pollutants, Beijing 100083, China |
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Abstract Catalytic purification has been developed to be a main technology involving with the removal of environmental pollutants. Microwave (MW) radiation with excellent performances of volatility, high frequency, thermal and non-thermal characteristics has caused widely attention. Therefore, MW-induced catalytic reactions play a vital role in improving environmental quality. With the continuous in-depth research of MW radiation and catalytic technology, the development of multifunctional materials with excellent MW absorbing performance and catalytic activity has become the focus of studies. According to the way of transforming the MW, wave-absorbing materials can be divided into three types, including dielectric loss, resistance loss and magnetic loss.The absorbing performance of the wave-absorbing materials is affected by various factors such as element composition, surface configuration and pore structure. In recent years, researchers have been improving the synthetic methods of wave-absorbing materials from the matching and attenuation characteristics, and have achieved substantial progress in enhancing the MW absorbing properties of mate-rials, and making full use of MW-induced catalytic reactions to improve the energy utilization rate as well as the degradation rate of environmental pollutants. Wave-absorbing materials will produce hot spot effect and discharge effect in the MW field. The MW-induced catalytic reaction changes the conventional thermal field to MW heating, which can realize the rapid temperature rise of the material at a lower environment temperature and achieve excellent catalytic performance. Metal materials can induce MW discharge in the MW field, and the discharge process will produce thermal effect, plasma effect and photocatalytic effect, which plays a crucial role in pollutant removal. However, since the reaction process of MW-induced cata-lysis is complicated, current studies have focused on distinguishing the influence of heat spot effect and discharge effect and clarifying the reaction pathway of MW-induced catalysis. Over the past years, a variety of catalysis with outstanding wave-absorbing and catalytic performances has been developed, and applied the MW-induced catalytic reaction to the purification treatment technology of waste water and exhaust gas, which has the advantages of fast reaction rate and high treatment efficiency. This paper mainly introduces the principle of MW absorption of materials, expounds the improvement of MW absorption properties of materials and the application of MW hot spot effect and discharge effect in pollutant removal, and discusses the future development direction of MW-induced catalytic reactions.
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Received: 25 September 2022
Published: 25 September 2022
Online: 2022-09-26
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Fund:The National Natural Science Foundation of China (21876010). |
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1 Subrahmanyam C, Renken A, Kiwi-Minsker L. Applied Catalysis B: Environmental, 2006, 65, 157. 2 Zhou Y L. Experimental and mechanism research of microwave-induced metal discharge on the degradation of biomass tar. Ph.D. Thesis, Shandong University, China, 2018(in Chinese). 周玉立. 微波诱导金属放电强化生物质焦油裂解试验与机理研究. 博士学位论文, 山东大学, 2018. 3 Yang Z Y. Studies of adsorption-desorption/catalytic oxidation of absor-bing materials under microwave radiation for purification of toluene vapor. Ph.D. Thesis, University of Science and Technology Beijing, China, 2019(in Chinese). 杨仲禹. 微波强化吸波材料吸-脱附/催化氧化气相甲苯研究. 博士学位论文, 北京科技大学, 2019. 4 García M C, Mora M, Esquivel D, et al. Chemosphere,2017,180,239. 5 Wang W L, Wang B, Sun J, et al. RSC Advances,2016,6(58),52974. 6 Wang W L, Zhao C, Sun J, et al. Energy, 2015, 87, 678. 7 Li J, Ng D H L, Song P, et al. Materials Science and Engineering: B, 2015, 194, 1. 8 Baghurst D R, Mingos D M P. Journal of the Chemical Society, Chemical Communications, DOI:10.1039/c39920000674. 9 Li F, Zhang M, Wang X D. The Chinese Journal of Proces Engineering, 2007, 7(1), 186(in Chinese). 李钒, 张梅, 王习东. 过程工程学报, 2007, 7(1), 186. 10 Ren C Y, Yi H H, Tang X L, et al. Modern Chemical Industry, 2019, 39(11), 20(in Chinese). 任晨阳,易红宏,唐晓龙, 等. 现代化工, 2019, 39(11), 20. 11 Liu Z. Research on the heating effects of metal discharge during microwave-induced pyrolysis of e-waste. Master's Thesis, Shandong Univer-sity, China, 2012(in Chinese). 刘振. 微波诱导热解电子废弃物过程中金属放电热效应研究. 硕士学位论文, 山东大学, 2012. 12 Ma Q L. Research on CH4-CO2 reforming effects caused by microwave-induced metal discharge. Master's Thesis, Shandong University, China, 2014(in Chinese). 马青峦. 微波诱导金属放电现象对CH4-CO2气体重整作用的研究. 硕士学位论文, 山东大学, 2014. 13 Wang W L, Fu L J, Sun J, et al. IEEE Transactions on Plasma Science, 2017, 45(8), 2235. 14 Sun J, Wang W L, Yue Q Y, et al. Applied Energy, 2016, 175, 141. 15 Peng Y D. Studies on microwave heating mechanism and sintering beha-vior of powder metallurgy materials. Ph.D.Thesis, Central South University, China, 2011(in Chinese). 彭元东. 微波加热机制及粉末冶金材料烧结特性研究. 博士学位论文, 中南大学, 2011. 16 Liu S H, Liu J M, Dong X L. Electromagnetic wave shielding and absor-bing materials, Chemical Industry Press, China, 2007(in Chinese). 刘顺华, 刘军民, 董星龙. 电磁波屏蔽及吸波材料, 化学工业出版社, 2007. 17 Garcia-Costa A L, Zazo J A, Rodriguez J J, et al. Applied Catalysis B: Environmental, 2017, 218, 637. 18 Jiang H T. Scientific and Technological Innovation,2019,24,180(in Chinese). 姜浩田. 科学技术创新, 2019, 24, 180. 19 Shen Z Z, Chen J H, Li B, et al. Journal of Alloys and Compounds, 2020, 815, 1. 20 Zhu B, Cui Y, Lv D F, et al. Materials Letters, 2020, 263, 1. 21 Singh S, Kumar A, Agarwal S, et al. Journal of Magnetism and Magnetic Materials, 2020, 503, 1. 22 Cheng J B, Zhao H B, Li M E, et al. Materials China, 2019, 38(9), 897(in Chinese). 程金波, 赵海波, 李蒙恩, 等. 中国材料进展, 2019, 38(9), 897. 23 Lu M M, Cao W Q, Shi H L, et al. Journal of Materials Chemistry A, 2014, 2(27), 10540. 24 Pang H F, Abdalla A M, Sahu R P, et al. Journal of Materials Science, 2018, 53(24), 16288. 25 Chabot V, Higgins D, Yu A P, et al. Energy & Environmental Science, 2014, 7(5), 1564. 26 Kong L, Yin X W, Xu H L, et al. Carbon, 2019, 145, 61. 27 Chen J, Meng P Y, Wang M L, et al. Journal of Alloys and Compounds, 2016, 679, 335. 28 Zhang S L, Jiao Q Z, Zhao Y, et al. Journal of Materials Chemistry A, 2014, 2(42), 18033. 29 Alam R S, Moradi M, Nikmanesh H, et al. Journal of Magnetism and Magnetic Materials, 2016, 402, 20. 30 Yu Z T, Wang Y P, Jiang L, et al. RSC Advances,2019,9(34),19729. 31 Xie Q L, Li S S, Gong R C, et al. Applied Catalysis B: Environmental, 2019, 243,455. 32 Yu Z T, Jiang L, Wang Y P, et al. Journal of Cleaner Production, 2020, 255, 1. 33 Wei Z S, Zeng G H, Xie Z R, et al. Journal of Environmental Enginee-ring, 2010, 136(12), 1403. 34 Jin Q H, Dai S S, Huang K M. Microwave chemical, Science Press, China, 1999(in Chinese). 金钦汉, 戴树珊, 黄卡玛. 微波化学, 科学出版社, 1999. 35 Garcia-Costa A L, Lopez-Perela L, Xu X Y, et al. Environmental Science and Pollution Research, 2018, 25(28), 27748. 36 Chen J, Xue S, Song Y T, et al. Journal of Hazardous Materials, 2016, 310, 226. 37 Xu D Y, Zhang Y S, Cheng F,et al. Journal of the Taiwan Institute of Chemical Engineers, 2016, 60, 376. 38 Yin J Y, Cai J J, Yin C, et al. Journal of Environmental Chemical Engineering, 2016, 4(1), 958. 39 Xu W T, Zhou J C, Li H, et al. Fuel Processing Technology, 2014, 127, 1. 40 Liu Z L, Meng H L, Li C, et al. Journal of Environmental Engineering, 2020, 146(4), 1. 41 Wei Z S, Luo Y W, Li B R, et al. Journal of Industrial and Engineering Chemistry, 2015, 24, 315. 42 Yi H H, Yang Z Y, Tang X L, et al. Chemical Engineering Journal, 2018, 333, 554. 43 Yang Z Y, Yi H H, Tang X L, et al. Jornal of Hazardous Materials, 2019, 373, 321. 44 Chen J N, Xu W T, Zhu J, et al. Applied Catalysis B: Environmental, 2020, 268, 1. 45 He Z M, Wang C, Chen C S. Journal of Nanoscience and Nanotechnology, 2020, 20(8), 4971. 46 Wang Y, Wang Y, Yu L, et al. Chemical Engineering Journal, 2019, 368, 115. 47 Wang Y, Yu L, Wang R T, et al. Journal of Colloid and Interface Science, 2020, 564, 392. 48 Wang Y, Wang Y, Yu L, et al. Chemical Engineering Journal, 2020, 390, 1. 49 Liu S. Preparation of monolithic molecular sieve-based catalysts and study on microwave catalytic combustion of VOCs. Master's Thesis, Xi'an University of Architecture and Technology, China, 2020(in Chinese). 刘双. 整体式分子筛基催化剂制备及微波催化燃烧VOCs特性研究. 硕士学位论文, 西安建筑科技大学, 2020. 50 Zhang T T. Selection of honeycomb catalyst carriers and microwave catalytic combustion of gaseous toluene. Master's Thesis, Xi'an University of Architecture and Technology, China, 2020(in Chinese). 张婷婷. 蜂窝催化剂载体优选及微波催化燃烧甲苯特性研究. 硕士学位论文, 西安建筑科技大学, 2020. 51 Chen J N. Study on highly effective direct decomposition of H2S into H2 and S by microwave catalysis and its microwave catalytic effects. Master's Thesis, Xiangtan University, China, 2020(in Chinese). 陈佳楠. 微波催化高效直接分解H2S制H2和S及其微波催化效应研究. 硕士学位论文, 湘潭大学, 2020. 52 Zhou Y L, Wang W L, Sun J, et al. Energy, 2017, 126, 42. 53 Sun J, Wang Q, Wang W L, et al. Energy, 2018, 155, 815. 54 Xue C. Study on discharge and catalysis during the process of microwave-assisted wet air oxidation. Master's Thesis, Shandong University, China, 2019(in Chinese). 薛超. 微波辅助湿式氧化过程的放电和催化效应研究. 硕士学位论文, 山东大学, 2019. 55 Wang Y C. Research on preparation and properties of cabon-encapsulated metal nonoparticles based on microwave-induced metal discharge. Master's Thesis, Shandong University, China, 2019(in Chinese). 王宜灿. 基于微波诱导金属放电的碳包覆金属纳米颗粒制备及性能研究. 硕士学位论文, 山东大学, 2019. 56 Hussain Z, Khan K M, Hussain K. Journal of Analytical and Applied Pyrolysis, 2010, 89(1), 39. 57 Zhou Y L, Wang W L, Sun J, et al. Applied Thermal Engineering, 2017, 125, 386. 58 Liu H Y, Yang J B, Qiao X L, et al. Energy & Fuels,2020,34(4),4384. 59 Feng Y K, Wang W L, Wang Y C, et al. Waste and Biomass Valorization, 2019, 10(12), 3921. 60 Sun J, Wang Q, Wang W L, et al. Fuel, 2018, 234, 1278. |
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