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Efficient Hydrogen Evolution on Antiperovskite CuNCo 3 Nanowires by Mo Incorporation and its Trifunctionality for Zn Air Batteries and Overall Water Splitting.

Jing QuZhongmin WangWeijiang GanRan XiaoXincheng YaoZeba KhanamLiuzhang OuyangHui WangHao YangShiguo ZhangM-Sadeeq Jie Tang Balogun
Published in: Small (Weinheim an der Bergstrasse, Germany) (2023)
The current development of single electrocatalyst with multifunctional applications in overall water splitting (OWS) and zinc-air batteries (ZABs) is crucial for sustainable energy conversion and storage systems. However, exploring new and efficient low-cost trifunctional electrocatalysts is still a significant challenge. Herein, the antiperovskite CuNCo 3 prototype, that is proved to be highly efficient in oxygen evolution reaction but severe hydrogen evolution reaction (HER) performance, is endowed with optimum HER catalytic properties by in situ-derived interfacial engineering via incorporation of molybdenum (Mo). The as-prepared Mo-CuNCo 3 @CoN nanowires achieve a low HER overpotential of 58 mV@10 mA cm -2 , which is significantly higher than the pristine CuNCo 3 . The assembled CuNCo 3 -antiperovskite-based OWS not only entails a low overall voltage of 1.56 V@10 mA cm -2 , comparable to most recently reported metal-nitride-based OWS, but also exhibits excellent ZAB cyclic stability up to 310 h, specific capacity of 819.2 mAh g -1 , and maximum power density of 102 mW cm -2 . The as-designed antiperovskite-based ZAB could self-power the OWS system generating a high hydrogen rate, and creating opportunity for developing integrated portable multifunctional energy devices.
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