Abstract
Single-atom layer clusters (SLCs) have demonstrated high catalytic potential owing to their fully exposed metal sites, alloying effects and unique electronic structures. However, the precise fabrication of bimetallic SLCs on a support remain challenging. Herein, a range of bimetallic M(1)M(2)-SLCs (M(1)M(2) = PdNi, PtCu, PtNi) with abundant and high-density diatomic alloy sites were precisely anchored onto carboxyl-functionalized carbon nanotubes (CNTs). Catalytic results showed that the resultant composite of PdNi-SLCs/CNTs was efficient for catalytic dehydrogenative silylation of H(2)O and alcohols, giving rise to diverse silanols and alkoxysilanes, respectively, in high yields. In particular, the turnover frequency and maximum turnover number of PdNi-SLCs/CNTs-catalyzed dehydrogenative silylation of water were up to 187 s(-1) and 964 737 based on Pd, respectively. Reaction mechanism studies revealed that the high catalytic performance was primarily attributed to the fully exposed structure of PdNi-SLCs and the cooperation between the Pd (δ-)-Ni (δ+) bimetallic clusters with asymmetric charge distribution, in which Pd rapidly dissociated the Si-H bond of silane, while the adjacent Ni-mediated H(2)O activation promoted the cleavage of the O-H bond, thereby facilitating the formation of silanol.