High Surface Area ZnO-Nanorods Catalyze the Clean Thermal Methane Oxidation to CO2

ZnO nanostructures were synthesized by a combination of non-aqueous and aqueous sol-gel techniques to obtain morphologically different ZnO nanostructures, nanorods, and nanopyramids, featuring oxygen vacancies-rich exposed lattice faces and exhibiting different catalytic properties and activity. In particular, ZnO nanorods with high surface area (36 m(2)/g) were obtained through a rapid, scalable, and convenient procedure. The materials were tested for complete methane oxidation as an important benchmark reaction that is sensitive to surface area and to the availability of oxygen vacancies. Simple ZnO nanorods derived from nanosized quantum dots showed the best catalytic performance that compared well to that of several literature-reported perovskites, mixed metal oxides, and single-metal oxides in terms of T-50 (576 degrees C) and T-90 (659 degrees C) temperatures. Such a result was attributed to their high surface-to-volume ratio enhancing the availability of catalytically active sites such as oxygen vacancies whose abundance further increased following catalytic application at high temperatures. The latter effect allowed us to maintain a nearly stable catalytic performance with over 90% conversion for 12 h at 700 degrees C despite sintering. This research shows that ZnO-based nanomaterials with a high surface area are viable alternatives to oxides of commonly applied (but of potentially limited availability) transition metals (La, Mn, Co, Ni) for the complete combustion of methane when working at moderate temperatures (600-700 degrees C).

Automated summary

ZnO nanostructures with different morphologies, nanorods, and nanopyramids were synthesized using non-aqueous and aqueous sol-gel techniques. The ZnO nanorods obtained through a rapid and scalable procedure exhibited high surface area. They showed excellent catalytic performance in complete methane oxidation at high temperatures, maintaining over 90% conversion for 12 hours at 700 degrees C. The high surface-to-volume ratio and abundant oxygen vacancies contributed to their enhanced catalytic activity.