Visible light plasmonic heating of Au-ZnO for the catalytic reduction of CO sub(2)

Plasmonic excitation of Au nanoparticles attached to the surface of ZnO catalysts using low power 532 nm laser illumination leads to significant heating of the catalyst and the conversion of CO sub(2) and H sub(2) reactants to CH sub(4) and CO products. Temperature-calibrated Raman spectra of ZnO phonons show that intensity-dependent plasmonic excitation can controllably heat Au-ZnO from 30 to similar to 600 degree C and simultaneously tune the CH sub(4) : CO product ratio. The laser induced heating and resulting CH sub(4) : CO product distribution agrees well with predictions from thermodynamic models and temperature-programmed reaction experiments indicating that the reaction is a thermally driven process resulting from the plasmonic heating of the Au-ZnO. The apparent quantum yield for CO sub(2) conversion under continuous wave (cw) 532 nm laser illumination is 0.030%. The Au-ZnO catalysts are robust and remain active after repeated laser exposure and cycling. The light intensity required to initiate CO sub(2) reduction is low ( similar to 2.5 10 super(5) W m super(-2)) and achievable with solar concentrators. Our results illustrate the viability of plasmonic heating approaches for CO sub(2) utilization and other practical thermal catalytic applications.