Adjusting Ag0 on oxygen-deficient Ag/MnO2 through electronic metal-support interaction to enhance mineralization of toluene in post-plasma catalytic system

[Display omitted] •EMSI was established between Ag and MnO2 by anchoring Ag onto hydroxyl groups.•EMSI intensity was regulated by oxygen vacancy concentration.•Enhanced EMSI promoted the generation of Ag0, converting O3 to O* with better oxidizing ability. While nonthermal plasma (NTP) technology ex...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2024-08, Vol.493, p.152572, Article 152572
Main Authors: Wen, Tiancheng, Liang, Liuguo, Wang, Lisha, Shao, Qi, Zhang, Jian, Long, Chao
Format: Article
Language:English
Subjects:
Deep oxidation
Electronic metal-support interaction
Nonthermal plasma
Oxygen vacancy
Sliver
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Summary:[Display omitted] •EMSI was established between Ag and MnO2 by anchoring Ag onto hydroxyl groups.•EMSI intensity was regulated by oxygen vacancy concentration.•Enhanced EMSI promoted the generation of Ag0, converting O3 to O* with better oxidizing ability. While nonthermal plasma (NTP) technology exhibits notable efficacy in removing volatile organic compounds (VOCs), its practical application is impeded by a restricted carbon dioxide (CO2) selectivity. In this work, Ag-loaded α-MnO2 nanorods with strong electronic metal-support interaction (EMSI) were synthesized to enhance the mineralization of toluene in post-plasma system (PPC). EMSI was constructed between Ag species and MnO2 by anchoring Ag on hydroxyl groups. Increasing Ag loading facilitated the generation of oxygen vacancies, which promoted electron transfer from MnO2 to Ag sites, reinforcing EMSI and favoring the formation of Ag0. The results showed that the 3% Ag-loaded α-MnO2 nanorods exhibited better activity than bare MnO2, with a remarkable boost in CO2 selectivity to 77.5%, far exceeding the 33% CO2 selectivity of MnO2. It was concluded that both oxygen vacancies and Ag0 affected the toluene conversion by enhancing the conversion of ozone (O3) to reactive oxygen species (ROS). Through in-situ DRIFTS, it was found that Ag0 transformed O3 to a higher concentration of atomic oxygen (O*), capable of degrading organic intermediates to CO2. Additionally, Ag0 facilitated the direct ring-opening of adsorbed toluene. This research introduces a novel method for designing catalysts with EMSI to improve the mineralization of VOCs.
ISSN:1385-8947
DOI:10.1016/j.cej.2024.152572