The Nature of Interfacial Catalysis over Pt/NiAl2O4 for Hydrogen Production from Methanol Reforming Reaction

Reforming of methanol is one of the most favorable chemical processes for on-board H2 production, which alleviates the limitation of H2 storage and transportation. The most important catalytic systems for methanol reacting with water are interfacial catalysts including metal/metal oxide and metal/carbide. Nevertheless, the assessment on the reaction mechanism and active sites of these interfacial catalysts are still controversial. In this work, by spectroscopic, kinetic, and isotopic investigations, we established a compact cascade reaction model (ca. the Langmuir- Hinshelwood model) to describe the methanol and water activation over Pt/NiAl2O4. We show here that reforming of methanol experiences methanol dehydrogenation followed by water-gas shift reaction (WGS), in which two separated kinetically relevant steps have been identified, that is, C-H bond rupture within methoxyl adsorbed on interface sites and O-H bond rupture within OlH (Ol: oxygen-filled surface vacancy), respectively. In addition, these two reactions were primarily determined by the most abundant surface intermediates, which were methoxyl and CO species adsorbed on NiAl2O4 and Pt, respectively. More importantly, the excellent reaction performance benefits from the following bidirectional spillover of methoxyl and CO species since the interface and the vacancies on the support were considered as the real active component in methanol dehydrogenation and the WGS reaction, respectively. These findings provide deep insight into the reaction process as well as the active component during catalysis, which may guide the design of new catalytic systems.

Automated summary

In this study, a compact cascade reaction model for the activation of methanol and water over Pt/NiAl2O4 was established by spectroscopic, kinetic, and isotopic investigations. Methanol reforming was found to involve methanol dehydrogenation and water-gas shift reaction. The dehydrogenation occurred via C-H bond rupture within methoxyl adsorbed on the interface, while the water-gas shift reaction occurred via O-H bond rupture within OlH adsorbed on the interface. These findings provide insight into the reaction process and active component during catalysis, guiding the design of new catalytic systems.