Electronic Structure Modulation Induced by Cobalt‐doping and Lattice‐Contracting on Armor‐Like Ruthenium Oxide Drives pH‐Universal Oxygen Evolution
Rui Gong, Bowen Liu, Xiaolei Wang, Shichao Du, Ying Xie, Wanqi Jia, Xinxin Bian, Zhimin Chen, Zhiyu Ren
Abstract
Abstract Exquisite design of RuO 2 ‐based catalysts to simultaneously improve activity and stability under harsh conditions and reduce the Ru dosage is crucial for advancing energy conversion involving oxygen evolution reaction (OER). Herein, a distinctive cobalt‐doped RuO x framework is constructed on Co 3 O 4 nanocones (Co 3 O 4 @CoRuO x ) as a promising strategy to realize above urgent desires. Extensive experimental characterization and theoretical analysis demonstrate that cobalt doped in RuO x lattice brings the oxygen vacancies and lattice contraction, which jointly redistribute the electron configuration of RuO x . The optimized d ‐band center balances the adsorption energies of oxygenated intermediates, lowing the thermodynamical barrier of the rate‐determining step; and meanwhile, the over‐oxidation and dissolution of Ru species are restrained because of the p ‐band down‐shifting of the lattice oxygen. Co 3 O 4 @CoRuO x with 3.7 wt.% Ru delivers the extremely low OER overpotentials at 10 mA cm −2 in alkaline (167 mV), neutral (229 mV), and acidic electrolytes (161 mV), and super operating stability over dozens of hours. The unprecedented activity ranks first in all pH‐universal OER catalysts reported so far. These findings provide a route to produce robust low‐loading Ru catalysts and an engineering approach for regulating the central active metal through synergy of co‐existing defects to improve the catalytic performance and stability.