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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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