The
oxygen evolution reaction (OER) plays an important role for
multiple energy conversion devices, such as electrochemical water
splitting, yet it suffers from high overpotential due to its sluggish
kinetics. As one of the most promising OER catalysts, NiFe layered
double hydroxides (LDHs) can be rationally tailored via defect engineering
to achieve enhanced catalytic performance. Herein, we report a fluoride
precovered surface strategy to manipulate the coordinatively unsaturated
metal sites of NiFe LDH catalysts. The adsorption of fluoride is introduced
during the crystallization process with flexible amount, and the precovered
fluoride can be easily removed by electrochemical treatment, leaving
a controllable density of unsaturated metal sites with high activity
toward OER. Specifically, NiFe LDH with an optimized amount of fluoride
precovered demonstrates an overpotential of 243 mV to achieve the
current density of 10 mA cm–2 for OER, with a reduced
Tafel slope of 50 mV dec–1, exhibiting enhanced
catalytic performance than pristine NiFe LDH. Such a precovered surface
strategy can effectively manipulate the density of coordinatively
unsaturated metal sites and has great potential in catalyst design
with high performance via defect engineering.
Ni–Fe dual-metal sites on NiFe-codoped polymeric carbon nitride co-participate in the OER process leading to significantly enhanced electrocatalytic activity.
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