Abstract Two-dimensional (2D) ferromagnetic materials with unique magnetic properties
have great potential for next-generation spintronic devices with high flexibility, easy …

Spin–orbit torque (SOT) is an emerging technology that enables the efficient manipulation of
spintronic devices. The initial processes of interest in SOTs involved electric fields, spin …

Oxide materials possess a vast range of functional properties, ranging from
superconductivity to multiferroicity, that stem from the interplay between the lattice, charge …

Efficient generation of spin–orbit torques is central for the exciting field of spin-orbitronics.
Platinum, the archetypal spin Hall material, has the potential to be an outstanding provider …

The search for efficient approaches to realize local switching of magnetic moments in
spintronic devices has attracted extensive attention. One of the most promising approaches …

Spin backflow and spin-memory loss have been well established to considerably lower the
interfacial spin transmissivity of metallic magnetic interfaces and thus the energy efficiency of …

Spin–orbit torques (SOTs) that arise from materials with large spin–orbit coupling offer a new
pathway for energy‐efficient and fast magnetic information storage. SOTs in conventional …

Transition-metal oxides (TMOs) constitute a key material family in spintronics because of
mutually coupled degrees of freedom and tunable magneto-ionic properties. In this …

Spin-orbit torque can drive electrical switching of magnetic layers. Here, we report that, at
least for micrometer-sized samples, there is no simple correlation between the efficiency of …

In transition‐metal‐oxide heterostructures, the anomalous Hall effect (AHE) is a powerful
tool for detecting the magnetic state and revealing intriguing interfacial magnetic orderings …