Litcius/Paper detail

Waveguide photoreactor enhances solar fuels photon utilization towards maximal optoelectronic – photocatalytic synergy

Joel Y. Y. Loh, Abhinav Mohan, Andrew G. Flood, Geoffery A. Ozin, Nazir P. Kherani

2021Nature Communications38 citationsDOIOpen Access PDF

Abstract

Abstract A conventional light management approach on a photo-catalyst is to concentrate photo-intensity to enhance the catalytic rate. We present a counter-intuitive approach where light intensity is distributed below the electronic photo-saturation limit under the principle of light maximization. By operating below the saturation point of the photo-intensity induced hydroxide growth under reactant gaseous H 2 +CO 2 atmosphere, a coating of defect engineered In 2 O 3- x (OH) y nanorod Reverse Water Gas Shift solar-fuel catalyst on an optical waveguide outperforms a coated plane by a factor of 2.2. Further, light distribution along the length of the waveguide increases optical pathlengths of the weakly absorptive green and yellow wavelengths, which increases CO product rate by a factor of 8.1-8.7 in the visible. Synergistically pairing with thinly doped silicon on the waveguide enhances the CO production rate by 27% over the visible. In addition, the persistent photoconductivity behavior of the In 2 O 3- x (OH) y system enables CO production at a comparable rate for 2 h after turning off photo-illumination, enhancing yield with 44-62% over thermal only yield. The practical utility of persistent photocatalysis was demonstrated through outdoor solar concentrator tests, which after a day-and-night cycle showed CO yield increase of 19% over a day-light only period.

Topics & Concepts

Materials scienceLight intensityPhotocatalysisVisible spectrumOptoelectronicsWaveguideYield (engineering)WavelengthNanorodOpticsCatalysisNanotechnologyChemistryPhysicsBiochemistryMetallurgyCatalytic Processes in Materials ScienceAdvanced Photocatalysis TechniquesCatalysis and Oxidation Reactions
Waveguide photoreactor enhances solar fuels photon utilization towards maximal optoelectronic – photocatalytic synergy | Litcius