Litcius/Paper detail

Surface photovoltage spectroscopy observes junctions and carrier separation in gallium nitride nanowire arrays for overall water-splitting

Rachel M. Doughty, Faqrul A. Chowdhury, Zetian Mi, Frank E. Osterloh

2020The Journal of Chemical Physics29 citationsDOIOpen Access PDF

Abstract

Gallium nitride (GaN) nanowire arrays on silicon are able to drive the overall water-splitting reaction with up to 3.3% solar-to-hydrogen efficiency. Photochemical charge separation is key to the operation of these devices, but details are difficult to observe experimentally because of the number of components and interfaces. Here, we use surface photovoltage spectroscopy to study charge transfer in i-, n-, and p-GaN nanowire arrays on n+-Si wafers in the presence and absence of Rh/Cr2O3 co-catalysts. The effect of the space charge layer and sub-bandgap defects on majority and minority carrier transport can be clearly observed, and estimates of the built-in potential of the junctions can be made. Transient illumination of the p-GaN/n+-Si junction generates up to −1.4 V surface photovoltage by carrier separation along the GaN nanowire axis. This process is central to the overall water-splitting function of the n+-Si/p-GaN/Rh/Cr2O3 nanowire array. These results improve our understanding of photochemical charge transfer and separation in group III–V semiconductor nanostructures for the conversion of solar energy into fuels.

Topics & Concepts

Surface photovoltageNanowireMaterials scienceWater splittingGallium nitrideOptoelectronicsSemiconductorDepletion regionWaferCarrier lifetimeBand gapSpectroscopyGalliumNitrideNanotechnologySiliconLayer (electronics)PhotocatalysisChemistryCatalysisPhysicsBiochemistryMetallurgyQuantum mechanicsGa2O3 and related materialsGaN-based semiconductor devices and materialsNanowire Synthesis and Applications