术引起了研究者的极大关注。 (1)中国是发表VOCs催化氧化相关论文最多的国家： (2)中国科学院大学是综合研究VOCs催化氧化最多的机构，浙江大学是单独研究（没有合 作)VOCs催化氧化最多的机构： (3)刊登VOCs催化氧化相关论文最多的期刊是Applied Catalysis B-Environmental: (4) 对VOCs催化氧化研究最常选用的主题是Chemistry和Engineering: (⑤)锰基催化剂是近5年应用于V0Cs催化氧化领域最多的元素： (6)甲苯是近5年应用于V0Cs催化氧化相关实验最多的反应底物。 现阶段我国虽然拥有着庞大的研究基数，但整体的V0Cs污染防治工作仍是处于摸索前进阶段， 督察力度不足、防治工作形式化、多数研究成果难以转化为实际生产力。中国既是人口大国，也是工 业强国，广大民众既要金山银山，又要绿水青山。研究者们应以行业需求为根本，以绿色发展为导 向，借鉴国内外研究热点，开发新型有机废气治理技术，形成工业污染控制技术体系 优化处理成 本与效果，推动行业超低排放升级改造，让可持续发展成为我国的时代符 of he n ne 参考文献 期刊：序号引作者.题名刊名，年，卷（期：起始页码 environment and photocatalytic oxidation State of the art.Environ Int,2007.33(5):694 [2]Ousmane M,et al.Supported Au catalysts for low-temperature abatement of propene and toluene,as model VOCs: Support effect.Appl Catal B-Emviron,2011.101(3)629 [3]Dudareva,N,et al.Plant Volatiles:Recent Advances and Future Perspectives.Crit Rev Plant SCl,2006.25(5):417 [4]Tassi F,et al.Volatile organic compounds (VOCs)in soil gases from Solfatara crater (Campi Flegrei,southern Italy): Geogenic source(s)vs.biogeochemical processes.Appl Geochem,2015.56:37 [5]Tassi F,et al.Sampling and analytical procedures for the determination of VOCs released into air from natural and anthropogenic sources:A comparison between SPME (Solid Phase Micro Extraction)and ST (Solid Trap)methods Appl Geochem,2012.27(1):145 [6 Montero-Montoya R,R Lopez Vargas and O Arellano-Aguilar.Volatile Organic Compounds in Air:Sources, Distribution.Exposure and Associated Illnesses in Children.Ann Glob Health.2018.84(2):225 [7]Hui L,et al.VOC characteristics,chemical reactivity and sources in urban Wuhan,central China.Atmos Emviron,2020. 224:117340. [8 Alberici,R.M.and WF.Jardim.Photocatalytic destruction of VOCs in the gas-phase using titanium dioxide.Appl Catal B-Environ.1997.14(1):55 [9 Zhang,L,et al.Adsorptive and catalytic properties in the removal of volatile organic compounds over zeolite-based materials.Chinese J Catal,2016.37(6):800 [10]Amann,M.and M.Lutz.The revision of the air quality legislation in the European Union related to ground-level ozoneq.J Hazard Mater,2000(78):41 [11]Li W.B.J.X.Wang and H.Gong,Catalytic combustion of VOCs on non-noble metal catalysts.Catal Today,2009. 148(1-2):81 [12]Belpomme D,et al.The multitude and diversity of environmental carcinogens.Emiron Res,2007.3(105):414 [13]Atkinson R.Atmospheric chemistry of VOCs and NOx.Atmos Emviron,2000.34(12):2063 [14]Zang M,et al.A review of recent advances in catalytic combustion of VOCs on perovskite-type catalysts.J Saudi术引起了研究者的极大关注。 (1) 中国是发表 VOCs 催化氧化相关论文最多的国家； (2) 中国科学院大学是综合研究 VOCs 催化氧化最多的机构，浙江大学是单独研究（没有合 作）VOCs 催化氧化最多的机构； (3) 刊登 VOCs 催化氧化相关论文最多的期刊是 Applied Catalysis B-Environmental； (4) 对 VOCs 催化氧化研究最常选用的主题是 Chemistry 和 Engineering； (5) 锰基催化剂是近 5 年应用于 VOCs 催化氧化领域最多的元素； (6) 甲苯是近 5 年应用于 VOCs 催化氧化相关实验最多的反应底物。 现阶段我国虽然拥有着庞大的研究基数，但整体的 VOCs 污染防治工作仍是处于摸索前进阶段， 督察力度不足、防治工作形式化、多数研究成果难以转化为实际生产力。中国既是人口大国，也是工 业强国，广大民众既要金山银山，又要绿水青山。研究者们应以行业需求为根本，以绿色发展为导 向，借鉴国内外研究热点，开发新型有机废气治理技术，形成工业污染控制技术体系，优化处理成 本与效果，推动行业超低排放升级改造，让可持续发展成为我国的时代符号。 参 考 文 献 期刊：[序号]作者.题名.刊名,年，卷(期):起始页码 [1] Wang S, H.M. Ang and M.O. Tade. Volatile organic compounds in indoor environment and photocatalytic oxidation: State of the art. Environ Int, 2007. 33(5): 694 [2] Ousmane M, et al. Supported Au catalysts for low-temperature abatement of propene and toluene, as model VOCs: Support effect. Appl Catal B-Environ, 2011. 101(3): 629 [3] Dudareva, N, et al. Plant Volatiles: Recent Advances and Future Perspectives. Crit Rev Plant SCI, 2006. 25(5): 417 [4] Tassi F, et al. Volatile organic compounds (VOCs) in soil gases from Solfatara crater (Campi Flegrei, southern Italy): Geogenic source(s) vs. biogeochemical processes. Appl Geochem, 2015. 56: 37 [5] Tassi F, et al. Sampling and analytical procedures for the determination of VOCs released into air from natural and anthropogenic sources: A comparison between SPME (Solid Phase Micro Extraction) and ST (Solid Trap) methods. Appl Geochem, 2012. 27(1): 115 [6] Montero-Montoya R, R López-Vargas and O Arellano-Aguilar. Volatile Organic Compounds in Air: Sources, Distribution, Exposure and Associated Illnesses in Children. Ann Glob Health, 2018. 84(2): 225 [7] Hui L, et al. VOC characteristics, chemical reactivity and sources in urban Wuhan, central China. Atmos Environ, 2020. 224: 117340. [8] Alberici, R.M. and W.F. Jardim. Photocatalytic destruction of VOCs in the gas-phase using titanium dioxide. Appl Catal B-Environ, 1997. 14(1): 55 [9] Zhang, L, et al. Adsorptive and catalytic properties in the removal of volatile organic compounds over zeolite-based materials. Chinese J Catal, 2016. 37(6): 800 [10] Amann, M. and M. Lutz. The revision of the air quality legislation in the European Union related to ground-level ozoneq. J Hazard Mater, 2000(78): 41 [11] Li W.B, J.X. Wang and H. Gong, Catalytic combustion of VOCs on non-noble metal catalysts. Catal Today, 2009. 148(1-2): 81 [12] Belpomme D, et al. The multitude and diversity of environmental carcinogens. Environ Res, 2007. 3(105): 414 [13] Atkinson R. Atmospheric chemistry of VOCs and NOx. Atmos Environ, 2000. 34(12): 2063 [14] Zang M, et al. A review of recent advances in catalytic combustion of VOCs on perovskite-type catalysts. J Saudi 录用稿件，非最终出版稿