Litcius/Paper detail

Photoelectrochemical Performance Improving Mechanism: Hybridization Appearing at the Energy Band of BiVO<sub>4</sub> Photoanode by Doped Quantum Layers Modification

Yang Li, Xianying Dai, Yuyu Bu, Hanzhi Zhang, Jie Liu, Wenyu Yuan, Xiaohui Guo, Jin‐Ping Ao

2022Small24 citationsDOI

Abstract

Abstract Surface passivation of the photoelectrode by wide bandgap semiconductor quantum layer is an important strategy to improve work stability and surface state inhibition. However, an inevitable energy barrier is generated during the quantum tunneling process of the photocarriers. To overcome this shortage, a tandem photo‐generated hole transfer route is fabricated on BiVO 4 photoanode by doped dual‐quantum layers modification, Ni‐ZnO (5 nm) and Rh‐SrTiO 3 (≈10 nm). Modulated photoelectrochemical (PEC), Scanning Kelvin Probe (SKP), and DFT calculation method results indicate that a tandem hole ohmic contact route is formed in the photoanode to reduce the quantum tunneling energy barrier, meanwhile, the photon absorption capacity of BiVO 4 is improved after doped quantum layers modification. Both a phenomenal attribute to the energy band hybridization between Ni, Rh 3d orbits in quantum layers with BiVO 4 photoanode. Then, the modified BiVO 4 photoanode achieves the recoded photocurrent density of 6.47 and 5.18 mA cm –2 (Na 2 SO 3 electrolyte, V RHE = 1.23 V) under simulated sun light (100 mW cm –2 AM 1.5 G) by xenon lamp illumination without and with UV composition cutting down to ≈5%, respectively. Generally, this work will highlight a potential application in the fields of PEC water splitting and photovoltaic conversion for various semiconductor nanomaterials.

Topics & Concepts

Materials scienceOptoelectronicsSemiconductorBand gapDopingPassivationQuantum efficiencyQuantum tunnellingOhmic contactPhotocurrentNanotechnologyPhotoelectrochemistryNanomaterialsPhotocathodeLayer (electronics)ElectrodeChemistryElectronPhysicsElectrochemistryPhysical chemistryQuantum mechanicsAdvanced Photocatalysis TechniquesGas Sensing Nanomaterials and SensorsCopper-based nanomaterials and applications
Photoelectrochemical Performance Improving Mechanism: Hybridization Appearing at the Energy Band of BiVO<sub>4</sub> Photoanode by Doped Quantum Layers Modification | Litcius