Optimized Microwave-Based Synthesis of Thermally Stable Inverse Catalytic Core–shell Motifs for CO2 Hydrogenation

The rational synthesis of Cu@TiO 2 core@shell nanowire (NW) structures was thoroughly explored using a microwave-assisted method through the tuning of experimental parameters such as but not limited to (i) controlled variation in molar ratios, (ii) the effect of discrete Ti precursors, (iii) the method of addition of the precursors themselves, and (iv) time of irradiation. Uniform coatings were obtained using Cu/Ti molar ratios of 1:2, 1:1, 2:1, and 4:1, respectively. It should be noted that although relative molar precursor concentrations primarily determined the magnitude of the resulting shell size, the dependence was nonlinear. Moreover, additionally important reaction parameters, such as precursor identity, the means of addition of precursors, and the reaction time, were individually explored with the objective of creating a series of optimized reaction conditions. As compared with Cu NWs alone, it is evident that both of the Cu@TiO 2 core-shell NW samples, regardless of pretreatment conditions, evinced much better catalytic performance, up to as much as 20 times greater activity as compared with standard Cu NWs. These results imply the significance of the Cu/TiO 2 interface in terms of promoting CO 2 hydrogenation, because TiO 2 alone is known to be inert for this reaction. Furthermore, it is additionally notable that the N 2 annealing pretreatment is crucial in terms of preserving the overall Cu@TiO 2 core@shell structure. We also systematically analyzed and tracked the structural and chemical evolution of our catalysts before and after the CO 2 reduction experiments. Indeed, we discovered that the core@shell wire motif was essentially maintained and conserved after this high-temperature reaction process, thereby accentuating the thermal stability and physical robustness of our as-prepared hierarchical motifs.