Oxide spin-orbitronics: spin-charge interconversion and topological spin textures

Oxide materials possess a vast range of functional properties, ranging from superconductivity to multiferroicity, that stem from the interplay between the lattice, charge, spin and orbital degrees of freedom, and electron correlations often play an important role in defining such properties. Historically, spin-orbit coupling was rarely a dominant energy scale in oxides. However, it recently became the focus of intense interest and was exploited to realize various exotic phenomena connected with real-space and reciprocal-space topology that may be harnessed in spintronics applications. In this Review, we survey the recent advances in the new field of oxide spin-orbitronics, with a special focus on spin-charge interconversion through the direct and inverse spin Hall and Edelstein effects, and on the generation and observation of topological spin textures, such as skyrmions. We also highlight the control of spin-orbit-driven effects by ferroelectricity and discuss the future perspectives for the field. Spin-orbit coupling can be leveraged to enable new functional properties in oxide materials, in particular, for spintronics applications. This Review surveys significant recent advances in the field of oxide spin-orbitronics and discusses its future perspectives.

Automated summary

Oxide materials exhibit a wide range of functional properties, where electron correlations and spin-orbit coupling play significant roles. Recent advances in oxide spin-orbitronics have led to the realization of exotic phenomena and new functionalities for spintronics applications. The future prospects for this field involve further exploration of spin-charge interconversion, topological spin textures, and the influence of ferroelectricity on spin-orbit-driven effects.