Defect-Confinement Strategy for Constructing CuO Clusters on Carbon Nanotubes for Catalytic Oxidation of AsH<sub>3</sub> at Room Temperature
Xinyu Yang, Jiayu Feng, Xingguang Hao, Li Zhao, Wenkai Xu, Yixing Ma, Xin Sun, Kai Li, Ping Ning, Fei Wang, Changbin Zhang
Abstract
The efficient removal of the highly toxic arsine gas (AsH 3 ) from industrial tail gases under mild conditions remains a formidable challenge. In this study, we utilized the confinement effect of defective carbon nanotubes to fabricate a CuO cluster catalyst (CuO/ACNT), which exhibited a capacity much higher than that of CuO supported on pristine multiwalled carbon nanotubes (MWCNT) (CuO/PCNT) for catalytically oxidizing AsH 3 under ambient conditions. The experimental and theoretical results show that nitric acid steam treatment could induce MWCNT surface structural defects, which facilitated more stable anchoring of CuO and then improved the oxygen activation ability, therefore leading to excellent catalytic performance. Density functional theory (DFT) calculations revealed that the catalytic oxidation of AsH 3 proceeded through stepwise dehydrogenation and subsequent recombination with oxygen to form As 2 O 3 as the final product.