LIMNO discovers new copper oxide deposition method
The in situ electro-conversion of an electrodeposited CuSCN film into Cu2O is reported to produce photocathodes with improved performance for solar hydrogen production.
Cuprous oxide, Cu2O, is an inexpensive semiconductor material currently under investigation for the direct conversion of sunlight into hydrogen, however preparing semitransparent and highly active films of Cu2O has been an ongoing challenge. In a new report from Caretti et al., the LIMNO lab in collaboration with LPI report a new route to construct thin homogeneous Cu2O layers on transparent fluorine doped tin oxide (FTO) substrates via the in-situ electro-conversion of CuSCN to Cu2O. We highlight the morphology control of the resulting converted Cu2O thin-films while demonstrating that they maintain promising performance for solar-driven hydrogen production with a maximum incident photon to current efficiency (IPCE) reaching 60% (at 0 V vs RHE and 450 nm) for a 180 nm-thick film and integrated solar photocurrents up to 4 mA cm–2. In addition, altering the deposition conditions (e.g., applied potential, electrolyte compositions and pH) gives important insight into the mechanism and operation of the electro-conversion process. Overall, we conclude that the converted Cu2O films are better suited for the coating of high surface transparent scaffolds or as top cells in tandem devices for overall water splitting. Thus, the Cu2O deposition by electro-conversion is a promising alternative to coat homogenous and thin Cu2O layer without scattering losses and without compromising the transparency of the electrode.
This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No 883264.