Ruddlesden–Popper
(R-P) perovskite oxides have attracted
much attention as highly active and stable bifunctional materials
for the oxygen evolution reaction (OER)/oxygen reduction reaction
(ORR) in alkaline solutions due to the nonuse of precious metal elements.
Herein, a triple (H+, O2–, and electron)
conductive R-P perovskite oxide, La1.2Sr0.8Ni0.6Fe0.4O4+δ, was prepared, and
the valence state of transition metal cations and highly oxidized
oxygen (O–/O22–) in
the structure was tuned by a low-temperature fluorine substitution
treatment. The homogeneous distribution of the fluorine elements across
the particles of the R-P perovskite oxide after its fluorination was
confirmed by high-resolution transmission electron microscopy (HRTEM)
images. By regulation of the amount of highly oxidative state oxygen
species and the valence state of transition metal cations in the R-P
perovskite structure, the material exhibits a significant enhancement
for both the OER and ORR electrocatalytic activities. The fluoridated
La1.2Sr0.8Ni0.6Fe0.4O4+δFy (LSNF-OF) achieves
a low OER overpotential of 308.1 mV in a 1 M KOH electrolyte at a
current density of 10 mA cm–2. This is superior
to both commercial Co3O4 and the pristine sample
without fluorination. The LSNF-OF electrode in an aqueous Zn-air battery
(ZAB) exhibits a peak power density of 19.15 W g–1 at a current density of 24 mA g–1. The low-temperature
trace fluorination can enhance the electrocatalytic efficiency of
perovskite oxides. This technique can be applied to various types
of metal oxides.