Activating Surface Lattice Oxygen of a Cu/Zn1–xCuxO Catalyst through Interface Interactions for CO Oxidation

Zeng, Minli; Wang, Xiyang; Yang, Qilei; Chu, Xuefeng; Chen, Zuolong; Li, Zhen; Redshaw, Carl; Wang, Chao; Peng, Yue; Wang, Nannan; Zhu, Yanqiu; Wu, Yimin A.

doi:10.1021/acsami.1c24321

Activating Surface Lattice Oxygen of a Cu/Zn1–xCuxO Catalyst through Interface Interactions for CO Oxidation

Zeng, Minli; Wang, Xiyang; Yang, Qilei; Chu, Xuefeng; Chen, Zuolong; Li, Zhen; Redshaw, Carl; Wang, Chao; Peng, Yue; Wang, Nannan; Zhu, Yanqiu; Wu, Yimin A.

Authors

Minli Zeng

Xiyang Wang

Qilei Yang

Xuefeng Chu

Zuolong Chen

Zhen Li

Carl Redshaw

Chao Wang

Yue Peng

Nannan Wang

Yanqiu Zhu

Yimin A. Wu

Abstract

Surface lattice oxygen in metal oxides is a common participant in many chemical reactions. Given this, the structural design of catalysts to activate lattice oxygen and moreover investigations into the effect of lattice oxygen on reaction pathways are hot topics. With this in mind, herein we prepare CuO–Zn1–xCuxO (ZCO) nanofibers akin to the Trojan horse legend and via an in situ reduction obtain activated Cu/Zn1–xCuxO (Cu/ZCO) nanofibers. X-ray absorption spectroscopy and X-ray photoelectron spectroscopy reveal that surface lattice oxygen of Cu/ZCO is effectively activated from inert O2– to reactive O2–x. This activation stems from the enhanced covalence of metal–oxygen bonds and the electron transfer between Cu and the support. Online mass spectrometry reveals that Cu/ZCO with activated lattice oxygen exhibits a higher Mars–van Krevelen reaction efficiency during the CO oxidation process. This study offers a new avenue to engineer interface interactions, given, as highlighted here, the importance of surface lattice oxygen in oxide supports during the catalytic process.

Citation

Zeng, M., Wang, X., Yang, Q., Chu, X., Chen, Z., Li, Z., Redshaw, C., Wang, C., Peng, Y., Wang, N., Zhu, Y., & Wu, Y. A. (2022). Activating Surface Lattice Oxygen of a Cu/Zn1–xCuxO Catalyst through Interface Interactions for CO Oxidation. ACS Applied Materials & Interfaces, https://doi.org/10.1021/acsami.1c24321

Journal Article Type	Article
Acceptance Date	Feb 2, 2022
Online Publication Date	Feb 10, 2022
Publication Date	Feb 10, 2022
Deposit Date	Feb 11, 2022
Publicly Available Date	Feb 11, 2023
Journal	ACS Applied Materials and Interfaces
Print ISSN	1944-8244
Electronic ISSN	1944-8252
Publisher	American Chemical Society
Peer Reviewed	Peer Reviewed
DOI	https://doi.org/10.1021/acsami.1c24321
Keywords	Surface lattice oxygen; Interface interactions; Active sites; CO oxidation; Reaction mechanism
Public URL	https://hull-repository.worktribe.com/output/3924710