Litcius/Paper detail

Enhanced solar water splitting using plasmon-induced resonance energy transfer and unidirectional charge carrier transport

Huaping Jia, Yat Lam Wong, Bingzhe Wang, Guichuan Xing, Chi Chung Tsoi, Meiling Wang, Wendong Zhang, Aoqun Jian, Shengbo Sang, Dangyuan Lei, Xuming Zhang

2021Optics Express11 citationsDOIOpen Access PDF

Abstract

Solar water splitting by photoelectrochemical (PEC) reactions is promising for hydrogen production. The gold nanoparticles (AuNPs) are often applied to promote the visible response of wideband photocatalysts. However, in a typical TiO 2 /AuNPs structure, the opposite transfer direction of excited electrons between AuNPs and TiO 2 under visible light and UV light severely limits the solar PEC performance. Here we present a unique Pt/TiO 2 /Cu 2 O/NiO/AuNPs photocathode, in which the NiO hole transport layer (HTL) is inserted between AuNPs and Cu 2 O to achieve unidirectional transport of charge carriers and prominent plasmon-induced resonance energy transfer (PIRET) between AuNPs and Cu 2 O. The measured applied bias photon-to-current efficiency and the hydrogen production rate under AM 1.5G illumination can reach 1.5% and 16.4 μmol·cm -2 ·h -1 , respectively. This work is original in using the NiO film as the PIRET spacer and provides a promising photoelectrode for energy-efficient solar water splitting.

Topics & Concepts

Materials scienceWater splittingPhotocathodeSurface plasmon resonanceOptoelectronicsNon-blocking I/OColloidal goldVisible spectrumSolar energyPlasmonCharge carrierOpticsNanoparticleElectronNanotechnologyPhotocatalysisChemistryPhysicsBiochemistryBiologyQuantum mechanicsCatalysisEcologyCopper-based nanomaterials and applicationsAdvanced Photocatalysis TechniquesZnO doping and properties