Magnetic Anisotropy Controlled by Distinct Interfacial Lattice Distortions at the LaSr CoO/LaSrMnO Interfaces.

Interface engineering is an important approach leading to multifunctional artificial materials. Although most of the previous works focused on the effects of the rotation/tilting of interfacial oxygen octahedron on perovskite multilayers, here, we report on a new kind of lattice distortion characterized by an off-center shift of the Mn ions within the MnO oxygen octahedra at the interfaces of LaSr CoO/LaSrMnO/LaSr CoO/LaAlO trilayers ( x = 0-1/3), which drives the initially perpendicularly aligned magnetic axis of the LaSrMnO (LSMO) film toward the in-plane direction, though the film is in a strongly compressive state. It is further found that the magnetic anisotropy considerably depends on the content of Sr in LaSr CoO, enhancing as x decreases. The maximal anisotropy constant at 10 K is +2.5 × 10 erg/cm for the trilayers with x = 0, whereas it is -1.5 × 10 erg/cm for a bare LSMO film on LaAlO. On the basis of the analysis of X-ray absorption spectroscopy and the results of density functional theory calculations, we found that the off-center displacement of the Mn ions has caused a strong orbital reconstruction at interfaces, resulting in the anomalous spin orientation against magnetoelastic coupling.