Interface charges redistribution enhanced monolithic etched copper foam-based Cu2O layer/TiO2 nanodots heterojunction with high hydrogen evolution electrocatalytic activity
Συγγραφέας
Long B., Yang H., Li M., Balogun M.-S., Mai W., Ouyang G., Tong Y., Tsiakaras P., Song S.Ημερομηνία
2019Γλώσσα
en
Λέξη-κλειδί
Επιτομή
Semiconducting materials are considered as excellent electrocatalysts for electrochemical water splitting; however, there is still a lack of relevant design and understanding of semiconducting composite electrodes. Here, a monolithic electrode composed of etched copper foam and p-n heterojunction (p-type Cu2O layer and n-type TiO2 nanodots with excellent hydrophilicity) is successfully prepared. This can reduce the electron transfer resistance, optimize water and H adsorption on catalyst surface and generate a space-charge region in phase interface, enhancing the local electrons density of Cu2O, which is proved by experimental results and density functional theory (DFT). Owing to the whole accelerated Volmer-Heyrovsky pathway, the as-prepared heterojunction electrode exhibits low onset potential (18 mV), high electrocatalytic activity (a potential of 114 mV at 10 mA cm−2) and long-term stability for hydrogen evolution reaction in alkaline media that is comparable to that of Pt, enabling the large scale fabrication. © 2018 Elsevier B.V.