Characterization of Cu(2)O/CuO heterostructure photocathode by tailoring CuO thickness for photoelectrochemical water splitting

Cu(2)O/CuO heterostructure is a well-known strategy to improve the performance of Cu(2)O photocathodes for photoelectrochemical (PEC) water splitting. The CuO thickness in the Cu(2)O/CuO heterostructure is considered as a critical factor affecting the PEC performance because it is highly related to the light utilization and charge separation/transport. In this study, the Cu(2)O/CuO photocathode tailoring the CuO thickness was investigated to examine the CuO thickness influence on the PEC performance. Cu(2)O/CuO photocathodes were prepared by the electrodeposition and subsequent thermal annealing process and the Cu(2)O/CuO heterostructure was controlled by the annealing temperature and time. It was demonstrated that the increased CuO thickness enhances the light absorption in the long wavelength region and improves the charge separation by the reinforced band bending. However, the thick CuO hinders the efficient charge transport in the Cu(2)O/CuO heterostructure, resulting in the decreased PEC performance. Therefore, it is necessary to optimize the CuO thickness for the enhanced PEC performance of Cu(2)O/CuO photocathodes. Consequently, the Cu(2)O/CuO photocathode consisting of the similar CuO thickness with its minority carrier diffusion length (∼90 nm) was fabricated by annealing at 350 °C for 20 min, and it shows the optimal PEC performance (−1.2 mA cm(−2) at 0 V vs. RHE) in pH 6.5 aqueous solution, resulting from the enhanced light utilization and the reinforced band bending.