Abstract
The development of low-cost, high-performance, and stable photoanodes is essential for solar-driven photoelectrochemical energy conversion. In(2)S(3), an n-type semi-transparent semiconductor (~2.0 eV), is particularly well-suited as a photoanode in PEC tandem devices. However, the Schottky barrier at the In(2)S(3)/FTO interface as well as the inherent defects in In(2)S(3) suppress charge extraction. This paper describes the design of a semi-transparent photoanode aimed at enhancing carrier mobility for unassisted water splitting. We incorporate a semi-transparent Ag layer at the FTO/In(2)S(3) interface to establish an ohmic contact, effectively resolving the conflict between light shielding of metal and the electron collection barrier from In(2)S(3) to FTO. Additionally, the In(2)S(3)/CdTe p-n heterojunction forms an effective built-in electric field, which serves as a strong driving force for the separation and migration of photogenerated charges. The Ag/Ag:In(2)S(3)/In(2)S(3)/CdTe/NiO(x)/TiO(2)/Ni semi-transparent photoanode exhibits a photocurrent density of 12.2 mA/cm(2) at 1.23 V vs. reversible hydrogen electrode, with stable operation for 60 h. Pairing a back-illuminated Si photocathode with an In(2)S(3)/CdTe semi-transparent photoanode enables a solar-to-hydrogen conversion efficiency of 5.10%.