Ferromagnetic polar metals via epitaxial strain: a case study of SrCoO3

Abstract

While polar metals are a metallic analogue of ferroelectrics, magnetic polar metals can be considered as a metallic analogue of multiferroics. There have been a number of attempts to integrate magnetism into a polar metal by synthesizing new materials or heterostructures. Here we use a simple yet widely used approach--epitaxial strain in the search for intrinsic magnetic polar metals. Via first-principles calculations, we study strain engineering of a ferromagnetic metallic oxide SrCoO3, whose bulk form crystallizes in a cubic structure. We find that under an experimentally feasible biaxial strain on the ab plane, collective Co polar displacements are stabilized in SrCoO3. Specifically, a compressive strain stabilizes Co polar displacements along the c axis, while a tensile strain stabilizes Co polar displacements along the diagonal line in the ab plane. In both cases, we find an intrinsic ferromagnetic polar metallic state in SrCoO3. In addition, we also find that a sufficiently large biaxial strain (> 4\%) can yield a ferromagnetic-to-antiferromagnetic transition in SrCoO3. Our work demonstrates that in addition to yielding emergent multiferroics, epitaxial strain is also a viable approach to inducing magnetic polar metallic states in quantum materials.

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