Nitrogen Doping-Induced Structural Distortion in LaMnO<sub>3</sub> Enhances Oxygen Reduction and Oxygen Evolution Reactions
Soumi Mondal, Shreya Sarkar, Mohd Riyaz, Manaswita Kar, Adrian Fortuin, Surishi Vashishth, Risov Das, Muthusamy Eswaramoorthy, Denis Kramer, Sebastian C. Peter
Abstract
Nitrogen-doped perovskites (LaMnO 3 ) were designed as bifunctional catalysts for oxygen reduction reaction (ORR) and oxygen evolution reaction (OER). Nitridation led to O-substitution in LaMnO 3, creating distortion in the LaMnO 3 structure and generating oxygen vacancies. N-doping facilitated an increase of Mn 3+ content, enhancing ORR and OER activities. LaMnO 3 with 4 h of nitridation exhibits 3.35 and 1.75 times higher specific and mass activities in comparison to pristine LaMnO 3 (highest reported among perovskite oxides). The enhancement in catalytic activity is attributed to the increase of Mn 3+ content and distorted Mn–O, leading to compressive strain. The substitution of N at the crystal lattice of perovskite stabilizes the intermediates through a combination of strain and charge modulation of the active Mn center, which causes the enhancement in ORR and OER performance. The bifunctional character of the catalyst was further evaluated for practical zinc–air battery applications in which nitrogen-doped LaMnO 3 undergoes steady operation up to 500 cycles in harsh industrial conditions of 6 M KOH.