| MATERIALS AND SUSTAINABLE DEVELOPMENT:ENVIRONMENT-FRIENDLY MATERIALS AND MATERIALS FOR ENVIRONMENTAL REMEDIATION |
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| Catalytic Removal of Toluene Over Manganese-Based Oxide Catalysts |
| YIN Ke1,2,3, CHEN Ruiyang1,2,3, LIU Zhiming1,2,3
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1 State Key Laboratory of Chemical Resources Engineering, Beijing University of Chemical Technology, Beijing 100029
2 College of Chemical Engineering, Beijing University of Chemical Technology, Beijing 100029, China
3 Beijing Key Laboratory of Energy and Environmental Catalysis, Beijing University of Chemical Technology, Beijing 100029 |
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Abstract The control of volatile organic compounds (VOCs) has attracted attention in both academic and industrial communities. Catalytic oxidation is considered to be one of the most promising methods for the removal of VOCs due to the high efficiency, low reaction temperature and low cost. The catalytic removal of toluene, which is one of the typical VOCs, is very important for the control of VOCs. Catalyst plays a key role for the catalytic oxidation of toluene. Considering the good redox property, high hydrothermal stability and the low cost of MnOx, many researchers have conducted intensive study on the catalytic oxidation of toluene over MnOx-based catalysts.
MnOx-based catalysts can be classified into heterogeneous MnOx, transition metal-doped MnOx and supported MnOx. For the heterogeneous MnOx, such as α@β-MnO2, the advantages of different MnOx phase can be made full use of. In addition, more oxygen vacancies are generated in the phase interface, promoting the oxygen flow and thereby improving the reaction efficiency. Introduction of transition metals to MnOx would contribute to the electron transfer between metals and enhance the oxygen mobility of the catalyst, thus enhancing the redox property. In the case of supported MnOx the strong metal-support interaction is beneficial for the improvement of the catalytic performance. Morphology control and the acid treatment of MnOx-based catalysts can also lead to improved activity by regulating the specific surface area, the active oxygen species and the redox ability of the catalysts. The oxidation of toluene on the MnOx-based catalyst follows Mars-van Krevelen (MVK) or Langmuir-Hinshelwood(L-H) mechanism. For both mechanisms the intermediate with an aromatic ring is formed.
In this review, the types of MnOx catalysts, influencing factors and mechanism of the catalytic oxidation of toluene over manganese-based oxide have been summarized and discussed. And the perspective on MnOx-based catalysts for the catalytic oxidation of toluene has been proposed.
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Published: 24 December 2020
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| Fund:This work was financially supported by the National Key R&D Program of China (2017YFC0210700) |
About author:: Ke Yin received her B.E. degree in Shandong University of Science and Technology in 2018. She is currently pursuing her M.E. at the Beijing University of Chemical Technology (BUCT), and is studying under the supervision of Prof. Zhiming Liu. Her research has focused on catalytic oxidation of benzene and toluene.
Zhiming Liu received his Ph.D. degree at Tsinghua University in 2004. He successively worked as a post-doctoral fellow in Korea Advanced Institute of Science and Technology (KAIST) (2004—2006), University of Alberta (2006) and Clemson University (2007—2008). In 2008 he joined in Beijing University of Chemical Technology. His research is focused on the environmental catalysis and air pollution control. He was selected as the Excellent Young Scholar of Fok Ying Tung Education Foundation in 2010 and New Century Excellent Talents of the Chinese Ministry of Education in 2013. |
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1 Sihaib Z, Puleo F, Garcia-Vargas J M, et al. Applied Catalysis B-Environmental,2017,209,689.
2 Atkinson R. Atmospheric Environment,2000,34(12-14),2063.
3 Li L, Liu S Q, Liu J X. Journal of Hazardous Materials,2011,192(2),683.
4 Kujawa J, Cerneaux S, Kujawski W. Journal of Membrane Science,2015,474,11.
5 Malhautier L, Quijano G, Avezac M, et al. Chemical Engineering Journal,2014,247,199.
6 Dinh M T N, Giraudon J M, Vandenbroucke A M, et al. Applied Catalysis B-Environmental,2015,172-173,65.
7 Mo J H, Zhang Y P, Xu Q J, et al. Atmospheric Environment,2009,43(14),2229.
8 Mao M Y, Li Y Z, Hou J T, et al. Applied Catalysis B-Environmental,2015,174-175,496.
9 Li J Q, Tang W X, Liu G, et al. Catalysis Today,2016,278,203.
10 Chen C Y, Wu Q M, Chen F, et al. Journal of Materials Chemistry A,2015,3(10),5556.
11 Huang H B, Leung D Y C. ACS Catalysis,2011,1(4),348.
12 Huang N, Qu Z P, Dong C, et al. Applied Catalysis A-General,2018,560,195.
13 Xie Y J, Yu Y Y, Gong X Q, et al. Crystengcomm,2015,17(15),3005.
14 Hu Z, Qiu S, You Y, et al. Applied Catalysis B-Environmental,2018,225,110.
15 Li G Q, Zhang C H, Wang Z, et al. Applied Catalysis A-General,2018,550,67.
16 Lahousse C, Bernier A, Grange P, et al. Journal of Catalysis,1998,178(1),214.
17 Xu H M, Yan N Q, Qu Z, et al. Environmental Science & Technology,2017,51,8879.
18 Du Y C, Meng Q, Wang J S, et al. Microporous and Mesoporous Mate-rials,2012,162(162),199.
19 Si W Z, Wang Y, Peng Y, et al. Chemical Communications,2015,51(81),14977.
20 Guo F, Xu J Q, Chu W. Catalysis Today,2015,256,124.
21 Kim S C, Shim W G. Applied Catalysis B-Environmental,2018,98(3-4),180.
22 Piumetti M, Fino D, Russo N. Applied Catalysis B-Environmental,2015,163,277.
23 Wang L, Zhang C H, Huang H, et al. Reaction Kinetics Mechanisms and Catalysis,2016,118(2),605.
24 Nguyen D M T, Nguyenb C C, Truong Vua T L, et al. Applied Catalysis A-General,2020,595,117473.
25 Zhou G L, Lan H, Gao T T, et al. Chemical Engineering Journal,2014,246,53.
26 Wang F, Yang G Y, Zhang W, et al. Chemical Communications,2013,34(33),1172.
27 Flavia G Durán, Barbero B P, Luis E Cadús, et al. Applied Catalysis B-Environmental,2009,92(1-2),194.
28 Saqer S M, Kondarides D I, Verykios X E. Applied Catalysis B-Environmental,2011,103(3-4),275.
29 Qu Z P, Gao K, Fu Q, et al. Catalysis Communications,2014,52,31.
30 Wang Y, Zhang L X, Guo L M. ACS Applied Nano Materials,2018,1(3),1066.
31 Behar S, Gonzalez P, Agulhon P, et al. Catalysis Today,2012,189(1),35.
32 Zhang C H, Guo Y L, Lu G, et al. Applied Catalysis B-Environmental,2014,148-149,490.
33 Liu Z X, Li W B. Acta Physico-Chimica Sinica,2016,32,1795.
34 Wang Y, Yang D Y, Li S Z, et al. Chemical Engineering Journal,2019,357,258.
35 Li W B, Chu W B, Zhuang M, et al. Catalysis Today,2004,93,205.
36 Montini T, Melchionnal M, Monai M, et al. Chemical Reviews,2016,116,5987.
37 Delimaris D, Ioannides T. Applied Catalysis B-Environmental,2018,84(1),303.
38 Du J P, Qu Z P, Dong C, et al. Applied Surface Science,2018,433,1025.
39 Dong Y L, Zhao J Y, Zhang J Y. et al. Chemical Engineering Journal,2020,388,124244.
40 Cui W H, Li S D, Wang D D, et al. Catalysis Communications,2019,119,86.
41 He C, Jiang Z Y, Ma M D, et al. ACS Catalysis,2018,8,4213.
42 Jung S C, Park Y K, Jung H Y, et al. Research on Chemical Interme-diates,2016,42(1),185.
43 Li X, Wang L J, Xia Q B, et al. Catalysis Communications,2011,14(1),15.
44 Yang L Y, Yang X, Lin S Y, et al. Catalysis Science & Technology,2015,5(3),1495.
45 Sultana A, Sasaki M, Hamada H. Catalysis Today,2012,185(1),284.
46 Shen B Y, Wang Y Y, Wang F M, et al. Chemical Engineering Journal,2014,236,171.
47 Hou Z Y, Feng J, Lina T, et al. Applied Surface Science,2018,434,82.
48 Lai X X, Feng J, Zhou X Y, et al. Acta Physico-Chimica Sinica,2020,36(8),1905047.
49 López-Fonseca R, Steltenpohl P, González-Velasco J R, et al. Studies in Surface Science Catalysis,2000,130,893.
50 Gallastegi-Villa M, Romero-Sáez M, Aranzabal A, et al. Catalysis Today,2013,213,192.
51 Li J R, Zuo S F, Qi C Z. Catalysis Communications,2017,323,160.
52 Romero-Sáez M, Divakar D, Aranzabal A, et al. Applied Catalysis B-Environmental,2016,180,210.
53 Huang H, Zhang C H, Wang L, et al. Catalysis Science & Technology,2016,6(12),4260.
54 Yang F, Gao S Y, Ding Y, et al. New Journal of Chemistry,2019,43(48),19020.
55 Liao Y N, Zhang X, Niu W H, et al. Environmental Engineering,2018,36(1),62(in Chinese).
廖银念,张璇,牛文浩,等.环境工程,2018,36(1),62.
56 Yang W H, Su Z A, Xu Z H, et al. Applied Catalysis B-Environmental,2020,260,118150.
57 Uematsu T, Miyamoto Y, Ogasawara Y, et al. Catalysis Science & Technology,2016,6(1),223.
58 Wang F, Dai H X, Deng J, et al. Environmental Science & Technology,2012,46(7),4034.
59 Shi F, Wang F J, Dai H X, et al. Applied Catalysis A-General,2012,433-434,206.
60 Ha T L, Kim H J, Shin J, et al. Chemical Communications,2011,47(32),9176.
61 Fu X B, Feng J Y, Wang H, et al. Catalysis Communications,2009,10(14),1844.
62 Liao Y N, Zhang X, Peng R, et al. Applied Surface Science,2017,405,20.
63 Li J Y, Qu Z P, Qin Y, et al. Applied Surface Science,2016,385,234.
64 Yang X Q, Yu X L, Lin M Y, et al. Catalysis Today,2019,327,254.
65 Si W Z, Wang Y, Zhao S, et al. Environmental Science & Technology,2016,50(8),4572.
66 Li B, Yang Q L, Peng Y, et al. Chemical Engineering Journal,2019,366,92.
67 He C H, Li P, Cheng J, et al. Water Air Soil Pollut,2010,209(1),365.
68 Chen J, Chen X, Xu W, et al. Chemical Engineering Journal,2017,330,281.
69 Zhang Z X, Jiang Z, Shangguan W F. Catalysis Today,2016,264,270.
70 Sun H, Liu Z G, Chen S, et al. Chemical Engineering Journal,2015,270,58.
71 Qin Y, Wang H, Dong C, et al. Journal of Catalysis,2019,380,21. |
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2020, Vol. 34 
