Architecture engineering of nanostructured catalyst via layer-by-layer adornment of multiple nanocatalysts on silica nanorod arrays for hydrogenation of nitroarenes

Direct consideration for both, the catalytically active species and the host materials provides highly efficient strategies for the architecture design of nanostructured catalysts. The conventional wet chemical methods have limitations in achieving such unique layer-by-layer design possessing one body framework with many catalyst parts. Herein, an innovative physical method is presented that allows the well-regulated architecture design for an array of functional nanocatalysts as exemplified by layer-by-layer adornment of Pd nanoparticles (NPs) on the highly arrayed silica nanorods. This spatially confined catalyst exhibits excellent efficiency for the hydrogenation of nitroarenes and widely deployed Suzuki cross-coupling reactions; their facile separation from the reaction mixtures is easily accomplished due to the monolithic structure. The generality of this method for the introduction of other metal source has also been demonstrated with Au NPs. This pioneering effort highlights the feasibility of physically controlled architecture design of nanostructured catalysts which may stimulate further studies in the general domain of the heterogeneous catalytic transformations.

Identifying signatures of thermal and non-thermal reaction pathways in plasmon induced H2 + D2 exchange reaction

In this work we demonstrate a strategy for identifying experimental signatures of thermal and non-thermal effects in plasmon mediated heterogeneous catalytic chemistry, a topic widely debated and discussed in the literature. Our method is based on monitoring the progress of plasmon-induced (or thermally-driven) reaction, carried out in a closed system, all the way to equilibrium. Initial part of evolution of the reaction provides information about kinetics, whereas at later times the equilibrium concentrations provide information about effective temperature at the reaction sites. Combining these two pieces of information we estimate the activation energies. Using this strategy on H 2 (g) + D 2 (g) <-->2 HD(g) isotope exchange reaction, catalyzed by Au nanoparticles under thermally-driven and light-induced conditions, we estimate the activation energies to be 0.75 ± 0.02 eV and 0.21 ± 0.02 eV, respectively. These vastly different activation energies observed are interpreted as a signature of different reaction pathways followed by the system under thermally-driven and light-induced conditions.

Chemical conversion based on crystal facet effect of transition metal oxide and construction methods for sharp-faced nanocrystals

The in-depth researches have found that the nanocrystal facet of transition metal oxide (TMO) greatly affects its heterogeneous catalytic performance, as well as the property of photocatalysis, gas sensing, electrochemical...