Crystal Phase Mediated Restructuring of Pt on TiO2 with Tunable Re-activity: Redispersion versus Reshaping

Restructuring of supported metal nanoparticles (NPs) e.g., reshaping and redispersion are of tremendous interest for the rational design of high-efficiency catalyst materials with precise particle sizes, shapes, and reactivities. Here we show a crystal phase mediated restructuring of Pt NPs on TiO2, as a simple approach for fabricating either atomically dispersed single atoms (SAs) or reshaped planar NPs of Pt catalysts with tunable reactivities. Utilizing a variety of state-of-the-art characterizations, we showed that rutile TiO2 favors the reshaping of 2D planar Pt NPs, whereas the anatase surface facilitates the redispersion of Pt NPs to SAs upon calcination in the air up to 400 oC. Environmental transmission electron microscopy (ETEM) and density function theory (DFT) calculations were employed to directly visualize the dynamic transformation of Pt NPs and reveal the specific role that TiO2 supports play in promoting the stability and diffusion of Pt SAs. As a result, the reverse reactivity was achieved by tunning their distinct restructuring behaviors. Thus, the Pt SAs on anatase TiO2 preferentially activated selective hydrogenation of phenylacetylene (21.22 x 10-2 s-1 at 50 oC), while planar Pt NPs on rutile significantly enhanced the combustion of methane (3.11 x 10-2 s-1 at 310 oC). Our results therefore open up new routes for tuning the restructuring behavior of supported metal catalysts and designing catalysts with controlled catalytic structures and reactivities.