Authors
MingYue Zhou, MaoChang Cao, XinXin Jin, JingHao Yang, ZiYue Wang, LiMin Dong, FangXu Yang
Published in
Langmuir : the ACS journal of surfaces and colloids. Jun 25, 2026. Epub Jun 25, 2026.
Abstract
Advancing the efficient and comprehensive control of volatile organic compounds (VOCs) is a critical cornerstone for establishing global atmospheric pollution prevention systems and achieving long-term improvements in air quality. Although catalytic oxidation is an effective technology for VOCs removal, its practical application is often limited by catalyst sintering and poor low-temperature activity. This study investigates the grain refinement and surface defect engineering of Cu-doped Mn3O4 spinel catalysts derived from metal-organic frameworks (MOFs) for low-temperature toluene oxidation. By controllably introducing Cu, crystal growth is effectively suppressed, and lattice distortion is induced, thereby increasing the density of surface defects. The optimized Cu0.03Mn2.97O4 sample exhibits enhanced surface oxygen mobility and modified cation distribution, promoting efficient oxygen activation and redox cycling, which significantly improves low-temperature catalytic activity, achieving a T90 value of 215 °C. Simultaneously, when the Cu0.03Mn2.97O4 catalyst was loaded onto porous Al2O3 ceramic, the gas diffusion efficiency was improved, and the agglomeration of the powder catalyst was effectively inhibited. The obtained Cu0.03Mn2.97O4/C catalyst reached T90 at 210 °C and maintained excellent stability during the toluene degradation test under 3 vol.% water vapor conditions for 50 consecutive hours. By integrating defect engineering with macroscopic structural design, this work elucidates the intrinsic structure-activity relationship, offering a practical strategy for doping engineering of transition metal oxide catalysts and their integration onto porous ceramic supports.
PMID:
42348275
Bibliographic data and abstract were imported from PubMed on 25 Jun 2026.
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