Engineering Steam Induced Surface Oxygen Vacancy onto Ni–Fe Bimetallic Nanocomposite for CO<sub>2</sub> Electroreduction
Qiang He, Yanxing Zhang, Haijing Li, Yang Yang, Shuai Chen, Wenjun Yan, Juncai Dong, Xian‐Ming Zhang, Xiujun Fan
Abstract
Abstract Surface oxygen vacancies (V o ) regulation is an effective strategy to improve the electrochemical CO 2 reduction reaction (CO 2 RR) performance by lowering the activation energy barrier of CO 2 ; however, the lack of precise control over the local atomic structures severely hinders the large‐scale application of V o ‐activated electrocatalyst for CO 2 RR. Herein, an efficient strategy to facilitate CO 2 activation is developed by introducing V o into transition metal nanoparticles (NPs) with a steam‐assisted chemical vapor deposition method. With the steam process, abundant surface V o are introduced into the assembled Ni–Fe bimetallic NPs composite (H‐NiFe/NG), which adjust surface Ni/Fe atoms to low‐valent coordinatively unsaturated Ni (+1)/Fe (+2) sites, serving as electron‐rich centers to adsorb and activate inert CO 2 molecules. The as‐prepared H‐NiFe/NG composite exhibits excellent catalytic performance with a maximum Faradaic efficiency of 94% at −0.80 V (vs RHE) for CO production with remarkable stability. The density function theory calculations corroborate that the Ni atoms around surface V o significantly lower the energy barrier for COOH* intermediate formation, which gives a low overpotential for reducing CO 2 to CO, exhibiting superior CO 2 RR performance. This general synthetic strategy provides a new insight to introduce surface V o on transition metal for efficient CO 2 reduction.