Lattice-distortion couplings in antiferroelectric perovskite AgNbO3 and comparison with PbZrO3

Abstract

Lead-free antiferroelectric perovskite AgNbO3 is nowadays attracting extensive research interests due to its promising applications in energy storage. Although great progress has been made in optimizing the material performance, fundamental questions remain regarding the mechanism stabilizing the antiferroelectric Pbcm phase. Here, combining structural symmetry analysis and first-principles calculations, we identified crucial anharmonic couplings of oxygen octahedra rotations and cation antipolar motions which contribute significantly to lowering the energy of the Pbcm phase. The stabilization of this phase shows close similarities with the stabilization of the Pbam phase in PbZrO3 except that in AgNbO3 the octahedra rotations are the primary distortions while the antipolar cation motions appear to be secondary. The appearance and significant amplitude of the latter are explained from the combination of hybrid-improper and triggered mechanisms.