Oxygen Vacancies Induced by Transition Metal Doping in γ-MnO 2 for Highly Efficient Ozone Decomposition

Transition metal (cerium and cobalt) doped γ-MnO (M-γ-MnO , where M represents Ce, Co) catalysts were successfully synthesized and characterized. Cerium-doped γ-MnO materials showed ozone (O ) conversion of 96% for 40 ppm of O under relative humidity (RH) of 65% and space velocity of 840 L g h after...

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Published in:Environmental science & technology 2018-11, Vol.52 (21), p.12685-12696
Main Authors: Li, Xiaotong, Ma, Jinzhu, Yang, Li, He, Guangzhi, Zhang, Changbin, Zhang, Runduo, He, Hong
Format: Article
Language:English
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Summary:Transition metal (cerium and cobalt) doped γ-MnO (M-γ-MnO , where M represents Ce, Co) catalysts were successfully synthesized and characterized. Cerium-doped γ-MnO materials showed ozone (O ) conversion of 96% for 40 ppm of O under relative humidity (RH) of 65% and space velocity of 840 L g h after 6 h at room temperature, which is far superior to the performance of the Co-γ-MnO (55%) and γ-MnO (38%) catalysts. Under space velocity of 840 L g h , the conversion of ozone over the Ce-γ-MnO catalyst under RH = 65% and dry conditions within 96 h was 60% and 100%, respectively, indicating that it is a promising material for ozone decomposition. XRD and HRTEM data suggested that Ce-γ-MnO formed mixed crystals consisting of α-MnO and γ-MnO with specific surface area increased from 74 m /g to 120 m /g compared to undoped γ-MnO , thus more surface defects were introduced. H -TPR, O -TPD, XPS, Raman, and EXAFS confirmed that Ce-γ-MnO exhibited more surface oxygen vacancies and surface defects, which play a key role during the decomposition of ozone. This study provides important insights for developing improved catalysts for gaseous ozone decomposition and promoting the performance of manganese oxide for practical ozone elimination.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.8b04294