Novel Cs-Mg-Al mixed oxide with improved mobility of oxygen species for passive NO<sub><i>x</i></sub> adsorption

Yimeng Yin; Chizhong Wang; Lei Qiu; Xing Li; Feilin Zhao; Jie Yu; Jinchi Han; Huazhen Chang

doi:10.1016/j.gee.2023.05.004

Volume 9 Issue 10

Oct. 2024

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Article Navigation > Green Energy&Environment > 2024 > 9(10): 1581-1591

Yimeng Yin, Chizhong Wang, Lei Qiu, Xing Li, Feilin Zhao, Jie Yu, Jinchi Han, Huazhen Chang. Novel Cs-Mg-Al mixed oxide with improved mobility of oxygen species for passive NOx adsorption. Green Energy&Environment, 2024, 9(10): 1581-1591. doi: 10.1016/j.gee.2023.05.004

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Yimeng Yin, Chizhong Wang, Lei Qiu, Xing Li, Feilin Zhao, Jie Yu, Jinchi Han, Huazhen Chang. Novel Cs-Mg-Al mixed oxide with improved mobility of oxygen species for passive NO_x adsorption. Green Energy&Environment, 2024, 9(10): 1581-1591. doi: 10.1016/j.gee.2023.05.004

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Novel Cs-Mg-Al mixed oxide with improved mobility of oxygen species for passive NO_x adsorption

doi: 10.1016/j.gee.2023.05.004

Abstract

Abstract

The development of passive NO_x adsorbers with cost-benefit and high NO_x storage capacity remains an on-going challenge to after-treatment technologies at lower temperatures associated with cold-start NO_x emissions. Herein, Cs₁Mg₃Al catalyst prepared by sol-gel method was cyclic tested in NO_x storage under 5 vol% water. At 100 ℃, the NO_x storage capacity (1219 μmol g^-1) was much higher than that of Pt/BaO/Al₂O₃ (610 μmol g^-1). This provided new insights for non-noble metal catalysts in low-temperature passive NO_x adsorption. The addition of Cs improved the mobility of oxygen species and thus improved the NO_x storage capacity. The XRD, XPS, IR spectra and in situ DRIFTs with NH₃ probe showed an interaction between CsO_x and AlO_x sites via oxygen species formed on Cs₁Mg₃Al catalyst. The improved mobility of oxygen species inferred from O₂-TPD was consistent with high NO_x storage capacity related to enhanced formation of nitrate and additional nitrite species by NO_x oxidation. Moreover, the addition of Mg might improve the stability of Cs₁Mg₃Al by stabilizing surface active oxygen species in cyclic experiments.
- Passive NO_x adsorber,
- Low-temperature NO_x storage,
- Cesium,
- Oxygen mobility

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[1]	J.N. Galloway, A.R. Townsend, J.W. Erisman, M. Bekunda, Z. Cai, J.R. Freney, L.A. Martinelli, S.P. Seitzinger, M.A. Sutton. Science. 320 (2008) 889-892.
[2]	B. Brunekreef, S.T. Holgate. Lancet. 360 (2002) 1233-1242.
[3]	Y. Yang, S. Zhao, L. Cui, F. Bi, Y. Zhang, N. Liu, X. Zhang, Green Energy & Environ 8 (2022) 654-672.
[4]	Q. Chen, D. Wang, C. Gao, B. Wang, S. Niu, G. Zhao, J. Crittenden, Green Energy & Environ. 8 (2023) 173-182.
[5]	Frey, H. C. J Air Waste Manage. 68 (2018) 514-563.
[6]	Johnson. T. SAE Int J Engines. 9 (2016) 1258-1275.
[7]	Bie. P, Deng. F, Chen. B, Wang. L, Yang. F, Zhou. J, He. K. Eco-Environ Health. 1 (2022) 156-164.
[8]	Gu. Y, Epling. W. S. Appl Catal A-Gen. 570 (2019) 1-14.
[9]	Chen. D, Lei. H, Xiong. W, Li. Y, Ji. X, Yang. J. Y, Ye. D. ACS Catal. 11 (2021) 13891-13901.
[10]	Theis. J. R, Lambert. C. K. Catal Today.258 (2015) 367-377.
[11]	Wang. J, Ji. Y, Jacobs. G, Jones. S, Kim. D. J, Crocker. M. Appl Catal B-Environ. 148 (2014) 51-61.
[12]	Theis. J. R. Catal Today. 267 (2016)93-109.
[13]	Roy. S, Baiker. A. Chem. Rev. 109 (2009) 4054-4091.
[14]	Castoldi. L, Nova. I, Lietti. L, Forzatti. P. Catal Today. 96 (2004) 43-52.
[15]	Nova. I, Castoldi. L, Lietti. L, Tronconi. E, Forzatti. P, Prinetto. F, Ghiotti. G. J Catal. 222 (2004) 377-388.
[16]	Piacentini. M, Strobel. R, Maciejewski. M, Pratsinis. S. E, Baiker. A. J Catal. 243 (2006) 43-56.
[17]	Liu. G, Gao. P. X. Catal Sci Technol. 1 (2011) 552-568.
[18]	Kim. B. S, Kim. P. S, Bae. J, Jeong. H, Kim. C. H, Lee. H. Environ. Sci. Technol. 53 (2019) 2900-2907.
[19]	Wang. X, Yu. Y, He. H.Appl Catal B-Environ. 100 (2010) 19-30.
[20]	Lee. J, Theis. J. R, & Kyriakidou. E. A. Appl Catal B-Environ. 243 (2019) 397-414.
[21]	Zhao. H, Hill. A. J, Ma. L, Bhat. A, Jing. G, & Schwank, J. W. Catal Sci Technol. 11 (2021) 5986-6000.
[22]	Ecker. S. I, Dornseiffer. J, Werner. J, Schlenz. H, Sohn. Y. J, Sauerwein. F. S, Meulenberg. W. A. Appl Catal B-Environ. 286 (2021) 119919.
[23]	Choi. Y, Jung. H, Kim. S, Han. J. W, Lee. K. B. Chem Eng J. 437 (2022) 135209.
[24]	Peng. Y, Si. W, Luo. J, Su. W, Chang. H, Li. J, Crittenden. J. Environ. Sci. Technol. 50 (2016) 6442-6448.
[25]	Hwang. J, Rao. R. R, Giordano. L, Akkiraju. K, Wang. X. R, Crumlin. E. J, Shao-Horn. Y. Nat Catal. 4 (2021) 663-673.
[26]	Wang. Z, Lin. F, Jiang. S, Qiu. K, Kuang. M, Whiddon. R, Cen. K.Fuel. 166 (2016) 352-360.
[27]	Gomez-Garcia. M. A, Pitchon. V, Kiennemann. A. Environ. Sci. Technol. 39 (2005) 638-644.
[28]	Filtschew. A, Stranz. D, Hess. C. Physical Chemistry Chemical Physics. 15 (2013) 9066-9069.
[29]	Atribak. I, Azambre. B, Lopez. A. B, Garcia-Garcia. A. Appl Catal B-Environ.92 (2009) 126-137.
[30]	Mihaylov. M. Y, Ivanova. E. Z, Aleksandrov. H. A, Petkov. P. S, Vayssilov. G. N, Hadjiivanov. K. I. Appl Catal B-Environ. 176 (2015) 107-119.
[31]	Ji. Y, Bai. S, Crocker. M. Appl Catal B-Environ. 170 (2015) 283-292.
[32]	Jones. S, Ji. Y, Crocker. M. Catal Lett. 146 (2016) 909-917.
[33]	Castoldi. L, Matarrese. R, Morandi. S, Righini. L, Lietti, L. Appl Catal B-Environ.224 (2018) 249-263.
[34]	Campbell. P. F, Ortner. M. H, Anderson. C. J. Anal Chem. 33 (1961) 58-61.
[35]	Takahashi. N, Matsunaga. S. I, Tanaka. T, Sobukawa. H, Shinjoh. H. Appl Catal B-Environ. 77 (2007) 73-78.
[36]	Gunnarsson. F, Pihl. J. A, Toops. T. J, Skoglundh. M, Harelind. H. Appl Catal B-Environ. 202 (2017) 42-50.
[37]	E. Michaelis, R. Nie, D. Austin, Y. Yue, Green Energy & Environ. 8(2023)1308-1324.
[38]	Qi. G, Li. W. Catal Today. 2012, 184 (1), 72-77.
[39]	Liang. Y, Ding. X, Zhao. M, Wang. J, Chen. Y. Appl Surf Sci. 443 (2018) 336-344.
[40]	Yu. J. J, Tao. Y. X, Liu. C. C, Hao. Z. P, Xu. Z. P. Environ. Sci. Technol. 41 (2007) 1399-1404.
[41]	Piacentini. M, Maciejewski. M, Burgi. T, Baiker. A. Top Catal. 30 (2004) 71-80.
[42]	Cui. C, Ma. J, Wang. Z, Liu. W, Liu. W, Wang. L. Catalysts. 9 (2019) 677.
[43]	Roy. S, van Vegten. N, Maeda. N, Baiker. Appl Catal B-Environ. 119 (2012) 279-286.
[44]	Wang. H, Srinath. N. V, Poelman. H, Detavernier. C, Li. P, Marin. G. B, Galvita. V. V. Catal Sci Technol. 10 (2020) 6987-7001.
[45]	Lykaki. M, Papista. E, Carabineiro. S. A, Tavares. P. B, Konsolakis. M. Catal Sci Technol. 8 (2018) 2312-2322.
[46]	Stefanov. P. Vacuum. 47 (1996) 1107-1110.
[47]	Li. Q, Xin. Y, Zhang. Z, Cao. X. Chem Eng J. 337 (2018) 654-660.
[48]	Ebina. T, Iwasaki. T, Onodera. Y, Chatterjee. A. Comp Mater Sci. 14 (1999) 254-260.
[49]	Iczkowski. R. P, Margrave. J. L. J. Am. Chem. Soc. 83 (1961) 3547-3551.
[50]	Kuljiraseth. J, Wangriya. A, Malones. J. M. C, Klysubun. W, Jitkarnka. S. Appl Catal B-Environ.243 (2019) 415-427.
[51]	Andersen. J. N, Lundgren. E, Nyholm. R, Qvarford. M. Surf Sci. 289 (1993) 307-334.
[52]	Sham. T. K, Shek. M. L, Hrbek. J. Surf Sci. 241 (1991) L16-L20.
[53]	Zhao. L, Zhang. Z, Li. Y, Leng. X, Zhang. T, Yuan. F, Zhu. Y. Appl Catal B-Environ. 245 (2019) 502-512.
[54]	Kustov. A. L, Makkee. M. Appl Catal B-Environ. 88 (2009)263-271.
[55]	Chen. X. Yu. E, Cai. S, Jia. H, Chen. J, Liang. P. Chem Eng J. 344 (2018) 469-479.
[56]	Lu. H. F, Zhou. Y, Han. W. F, Huang. H. F, Chen. Y. F. Appl Catal A-Gen. 464 (2013) 101-108.
[57]	Olsson. L, Persson. H, Fridell. E, Skoglundh. M, Andersson. B. J. Phys. Chem. B. 105 (2001) 6895-6906.
[58]	He. J, Zhai. Q, Zhang. Q, Deng. W, Wang. Y. J Catal. 299 (2013) 53-66.
[59]	Wang. D, Zhang. L, Kamasamudram. K, Epling. W. S. ACS Catal.3 (2013) 871-881.
[60]	Wang. D, Gao. F, Peden. C. H, Li. J, Kamasamudram. K, Epling. W. S. ChemCatChem. 6 (2014) 1579-1583.
[61]	Chang. H, Li. M, Li. Z, Duan. L, Zhao. C, Li. J, Hao. J. Catal Sci Technol. 7 (2017) 2057-2064.
[62]	Chang. H, Li. J, Su. W, Shao. Y, Hao. J. Chem Commun. 50 (2014) 10031-10034.
[63]	Mo. S, Zhang. Q, Li. J, Sun. Y, Ren. Q, Zou. S, Ye. D. Appl Catal B-Environ. 264 (2020) 118464.
[64]	Feng. Z, Ren. Q, Peng. R, Mo. S, Zhang. M, Fu. M, Ye. D. Catal Today. 332 (2019) 177-182.
[65]	Yang. W, Wang. Y, Yang. W, Liu. H, Li. Z, Peng. Y, Li. J. ACS Appl. Mater. Interfaces. 13 (2021) 2753-2764.
[66]	Hadjiivanov. K. I. Catal Rev. 42 (2000) 71-144.
[67]	Epling. W. S, Peden. C. H, Szanyi. J. J. Phys Chem. C. 112 (2008) 10952-10959.
[68]	Sedlmair. C, Seshan. K, Jentys. A, Lercher. J. A. J Catal. 214 (2003) 308-316.

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Novel Cs-Mg-Al mixed oxide with improved mobility of oxygen species for passive NO_x adsorption

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Novel Cs-Mg-Al mixed oxide with improved mobility of oxygen species for passive NOx adsorption

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Novel Cs-Mg-Al mixed oxide with improved mobility of oxygen species for passive NO_x adsorption