CeO sub(2) nanodots embedded in a porous silica matrix as an active yet durable catalyst for HCl oxidation

A unique architecture of CeO sub(2) nanodots embedded in a porous SiO sub(2) matrix (CeO sub(2)iO sub(2)) was successfully fabricated by a spontaneous deposition strategy and evaluated in the recycling of Cl sub(2) from HCl oxidation. The nano-sized CeO sub(2) particles with a narrow size distributi...

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Veröffentlicht in:Catalysis science & technology 2016-06, Vol.6 (13), p.5116-5123
Hauptverfasser: Chen, Xian, Xu, Xihua, Fei, Zhaoyang, Xie, Xingxing, Lou, Jiawei, Tang, Jihai, Cui, Mifen, Qiao, Xu
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container_end_page 5123
container_issue 13
container_start_page 5116
container_title Catalysis science & technology
container_volume 6
creator Chen, Xian
Xu, Xihua
Fei, Zhaoyang
Xie, Xingxing
Lou, Jiawei
Tang, Jihai
Cui, Mifen
Qiao, Xu
description A unique architecture of CeO sub(2) nanodots embedded in a porous SiO sub(2) matrix (CeO sub(2)iO sub(2)) was successfully fabricated by a spontaneous deposition strategy and evaluated in the recycling of Cl sub(2) from HCl oxidation. The nano-sized CeO sub(2) particles with a narrow size distribution (2-4 nm) were uniformly dispersed in the amorphous SiO sub(2) matrix. Based on the characterizations from various techniques, including XRD, SEM/(HR)TEM, H sub(2)-TPR, Raman, and XPS, it was revealed that the CeO sub(2) nanodots in the SiO sub(2) matrix exhibited a significant "size effect", with characteristics such as a considerably high concentration of Ce super(3+), a high fraction of oxygen vancant sites, and a notably enhanced oxygen reducibility, which all affect oxygen activation and surface Cl desorption. The current CeO sub(2)iO sub(2) catalyst shows superior activity (1.60 g sub(Cl) sub(2)g sub(cat) super(-1) h super(-1)) and good durability (an on-stream time of 100 h at 703 K). The isolation of fine CeO sub(2) nanodots by the SiO sub(2) matrix is a key factor in the inhibition of sintering of CeO sub(2) entities. Kinetic measurements indicate that catalytic activity is more dependent on the O sub(2) partial pressure than that of HCl, suggesting that enhancement in oxygen adsorption and surface Cl desorption is crucial for improving the catalytic activity.
doi_str_mv 10.1039/c5cy02300a
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source Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects Catalysts
Catalytic activity
Durability
Nanostructure
Oxidation
Oxygen
Silicon dioxide
Surface chemistry
title CeO sub(2) nanodots embedded in a porous silica matrix as an active yet durable catalyst for HCl oxidation
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