PdAu nanosheets for visible-light-driven Suzuki cross-coupling reactions
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Holmes, Justin D.
American Chemical Society
Combining a two-dimensional (2D) morphology and plasmonic photocatalysis represents an efficient design for light-driven organic transformations. We report a one-pot synthesis of surfactant templated PdAu nanosheets (NSs). Transmission electron micros-copy (TEM) and X-ray photoelectron spectroscopy (XPS) analyses show the formation of 2D PdAu structures was initiated through nanoparticle seeds dispersed in the alkyl ammonium salt surfactant which acted as a template for the growth into NSs. The PdAu NSs were used for visible-light-enhanced Suzuki cross coupling. The PdAu bimetallic NSs outperformed monometallic Pd NSs and commercial Pd/C in room-temperature Suzuki cross-coupling reactions. The high catalytic act i v i t y is attributed to a combination of the 2D morphology giving rise to plasmon-enhanced catalysis and a high density of surface atoms, the electron-rich Pd surface due to alloying, and the presence of weakly bound amines. A comparative study of surfactant-assisted NSs and CO-assisted NSs was also carried out to assess the influence of surface ligands on the catalytic and photocatalytic enhancement of NSs with similar morphology. The surfactant-assisted NSs showed substantially superior performance compared to the CO-assisted for room-temperature Suzuki coupling reactions.
Palladium nanosheets , Catalytic-activity , Nanoparticles , Surface , Photocatalyst , Morphology , Silica , Energy
Casey, É., Holmes, J.D. and Collins, G. (2022) ‘Pdau nanosheets for visible-light-driven suzuki cross-coupling reactions’, ACS Applied Nano Materials, 5(11), pp. 16196–16206. doi: 10.1021/acsanm.2c03216.
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