Benchmarking superfast electrodeposited bimetallic (Ni, Fe, Co, and Cu) hydroxides for oxygen evolution reaction

High-performing electrocatalysts of oxygen evolution reaction (OER) are essential for various clean energy devices. Due to their excellent OER performance, transition metal layered doubled hydroxides (LDHs) attract increasing interest. Herein, a systematic study of superfast single-step synthesis for a series of carbon-free, binder-free self-supported bimetallic hydroxides on Ni foam (NF) and their associated performance towards OER in alkaline electrolytes is presented. Transition metal hydroxides are directly deposited on NF by a superfast electrodeposition technique. The resultant bimetallic hydroxides are uniformly distributed over NF in short-range order crystalline or amorphous structures. All six electrodes demonstrate significantly greater OER activities than ruthenium oxide (RuO2). The interaction between transition metal LDHs and NF determines OER performance. Applying optimum conditions, the highest activities are accomplished. Overall, results show excellent OER performance. The fast electrodeposition technique provides a systematic and cost-effective way to achieve durable self-supported transition metal LDH structures showing excellent OER performance. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

This study presents a systematic investigation of superfast single-step synthesis for a series of carbon-free, binder-free self-supported bimetallic hydroxides on Ni foam and their performance towards OER in alkaline electrolytes. The bimetallic hydroxides show significantly greater OER activities than ruthenium oxide, demonstrating excellent OER performance.