Effect of Biaxial Strain on Cation Octahedral Rotations and Magnetic Structure of the Antiperovskite Mn3GaN
Abstract
Density functional theory is used to study the effect of compressive and tensile biaxial strain on Mn3GaN. Mn3GaN is a non-collinear antiferromagnetic antiperovskite with a similar structure to that of an ideal cubic oxide perovskite, but with cations at the octahedral sites while the anion, nitrogen, is found at the B site. The present study explores the response of Mn3GaN to (001) strain, considering biaxial strain levels ranging from -5% to 5%. It is found that the electron structure is insensitive to tensile strain. The study supports previous results in that a spin-canted antiferromagnetic order emerges due to tensile strain, inducing net magnetization. Compressive strain collapses the non-collinear antiferromagnetic spin structure and induces a ferrimagnetic order at -2% strain. Notably, in contrast with oxide perovskites, Mn3GaN does not respond to strain by octahedral tilt, but rather by intraband redistributions of charge between Mn d states. Despite the similar structure to oxide perovskites, the bonds between the B site anion and octahedral site cations in Mn3GaN bonds are less rigid, such that strain is instead accommodated by a change in bond length rather than a change in bond angles.
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