Interfacial engineering of CeO <sub>2</sub> on NiCoP nanoarrays for efficient electrocatalytic oxygen evolution
Menghan Gao, Zhihong Wang, Shichao Sun, Deli Jiang, Min Chen
Abstract
Abstract Transition metal phosphides (TMP)-based oxygen evolution reaction (OER) catalysts constructed by interface engineering strategy have a broad prospect due to their low cost and good performance. Herein, a novel CeO 2 /NiCoP nanoarray with intimate phosphide (NiCoP)-oxide (CeO 2 ) interface was developed via in situ generation on nickel foam (NF). This structure is conducive to increasing active sites and accelerating charge transfer, and may be conducive to regulating electronic structure and adsorption energy. As expected, optimal 1.4-CeO 2 /NiCoP/NF delivers a low overpotential of 249 mV at the current density of 10 mA cm −2 with a Tafel slope of 77.2 mV dec −1 . CeO 2 /NiCoP/NF boasts one of the best OER catalytic materials among recently reported phosphides (TMP)-based OER catalysts and composite catalysts involving CeO 2 . This work provides an effective strategy for the construction of hetero-structure with CeO 2 with oxygen vacancies to improve the OER performance of phosphides.