Ceria-doped UiO-66-derived carbon–zirconia supported vanadium catalysts for CO2-ODHP: Synergistic effects of MSI tuning, oxygen vacancies, and spillover behavior
Zahra Mokhtari, Jafar Towfighi Darian, Masoud Safari Yazd
Abstract
In this study, a series of zirconia-supported vanadium oxide catalysts—VZ (V 2 O 5 @ZrO 2 ), VZC (V 2 O 5 @ZrO 2 /C, UiO-66-derived), and Ce-VZC (Ce-doped-V 2 O 5 @ZrO 2 /C)—were synthesized and systematically evaluated for the CO 2 -assisted oxidative dehydrogenation of propane (ODHP). The incorporation of a carbonaceous framework derived from UiO-66 and the strategic doping of ceria were employed to optimize metal-support interactions (MSI), enhance oxygen vacancy formation, and promote the spillover of key intermediates. A comprehensive characterization strategy—including XRD, FT-IR, HR-XPS, FE-SEM/EDS, BET, H 2 -TPR, and H 2 /CO 2 -TPD—combined with DFT calculations was undertaken to correlate structure–property–performance relationships. The results reveal that Ce-VZC exhibited the highest surface basicity, active site dispersion, reducibility, and oxygen vacancy concentration, all of which translated into superior catalytic performance and stability. DFT calculations confirmed the lowered energy barriers for propane dehydrogenation and CO 2 activation in Ce-VZC, while also demonstrating moderated MSI and longer spillover distances of H, O, and CO 2 species. Among the catalysts, Ce-VZC achieved the highest propane conversion (19.3 %) and propylene yield (13.9 %) with excellent stability over 600 min of time-on-stream. This work highlights the synergistic effect of ceria doping and carbon integration in tuning MSI, redox properties, and intermediate spillover, offering a promising route toward the rational design of high-performance ODHP catalysts. • Ce-VZC catalyst shows highest propane conversion and propylene yield. • Ceria doping enhances oxygen vacancies, MSI moderation, and spillover. • Carbon framework from UiO-66 improves redox and surface properties. • Structure–performance relationships confirmed by experimental and DFT analysis. • Sustainable catalyst design advances efficient CO 2 -assisted ODHP.