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论文类型：期刊论文

第一作者：Liu, Yang

通讯作者：Liu, Y (reprint author), Dalian Univ Technol, Key Lab Ind Ecol & Environm Engn, Minist Educ, Sch Food & Environm, Panjin 124221, Peoples R China.

合写作者：Zhou, Hao,Cao, Ranran,Sun, Tao,Zong, Wenjing,Zhan, Jingjing,Liu, Lifen

发表时间：2019-01-01

发表刊物：MATERIALS CHEMISTRY AND PHYSICS

收录刊物：SCIE

卷号：221

页面范围：457-466

ISSN号：0254-0584

关键字：Catalytic decomposition; Benzene; Manganese dioxide; Cerium doping; Water vapor

摘要：In this study, Mo6+ and Ce3+, which are the typical high- and low-valence modifiers, were comparatively used as structural and catalytic promoters for bimessite-type MnO2 to remove gaseous benzene. Various characterizations were performed to elaborate how the surface properties of the nanomaterials led to the observed catalytic behaviors. The Mo species existed as highly dispersed MoO3 over the Mo-MnO2 while Ce was incorporated into the MnO2 lattice. The activities of the lattice oxygen and oxygen vacancies over the Mo-MnO2 were comparable to those of the pristine Mn0 2 , thus resulting in similar catalytic performance. However, the replacement of lattice Mn by Ce inhibited the regular growth of the birnessite crystals and caused distortion of MnO2 lattice. Thanks to the high activity of the lattice oxygen, oxygen vacancies and surface adsorbed oxygen, benzene decomposition was significantly improved over the Ce-MnO2. Ce-MnO2 (0.8) with a nominal Ce/Mn atomic ratio of 0.8 exhibited stable conversion of similar to 90% for 395 ppm of benzene in dry gas under 120 L g(-1)h(-1) of space velocity and 350 degrees C. Moreover, under similar reaction conditions, the Ce-MnO2 (0.8) could also stand up water vapor and kept a moderate activity of 60% with 50% of relative humidity.