Semi-metallic bulk generated spin-orbit torques in disordered topological insulator

Spin-orbit torque (SOT) induced by the transfer of orbital angular momentum from a lattice to a spin system offers an efficient route for manipulating spin-based devices. Among various potential candidates, three-dimensional topological insulators (TIs) with inherently strong spin-orbit coupling promise to be a powerful source of SOTs. While the huge SOTs observed in ferromagnet (FM)/TI bilayers are generally claimed to be of topological surface states (TSS) nature, the contributions from the surface and bulk states in realistic systems are undistinguishable, rendering the underlying physics elusive. Here, we provide direct evidence that the bulk spin-Hall effect dominates the SOTs generated by disordered TIs. We show that sizable SOTs with clear bulk feature are generated by bismuth antimonides, in which the semi-metallic bulk state intermediately couples to the surface states. From our analysis based on a drift diffusion approach, the lower limit of spin Hall conductivity turns out to be $0.66 \times 10 ^{5} (\hbar/2e)$ $\Omega$$^{-1}$m$^{-1}$, which is comparable to the reported values against the general belief in TSS origin. Furthermore, the complementary results of SOT generation and Gilbert damping enhancement suggest an essential role of band bending near the FM/TI interface upon modifying the relative magnitude of the real and imaginary parts of spin mixing conductance. Together with the bulk spin Hall effect, our finding may alter the landscape of the field of spin-orbitronics in TI based systems and develop new applications such as SOT transistors

Impact of inherent energy barrier on spin-orbit torques in magnetic-metal/semimetal heterojunctions

Abstract Spintronic devices are based on heterojunctions of two materials with different magnetic and electronic properties. Although an energy barrier is naturally formed even at the interface of metallic heterojunctions, its impact on spin transport has been overlooked. Here, using diffusive spin Hall currents, we provide evidence that the inherent energy barrier governs the spin transport even in metallic systems. We find a sizable field-like torque, much larger than the damping-like counterpart, in Ni81Fe19/Bi0.1Sb0.9 bilayers. This is a distinct signature of barrier-mediated spin-orbit torques, which is consistent with our theory that predicts a strong modification of the spin mixing conductance induced by the energy barrier. Our results suggest that the spin mixing conductance and the corresponding spin-orbit torques are strongly altered by minimizing the work function difference in the heterostructure. These findings provide a new mechanism to control spin transport and spin torque phenomena by interfacial engineering of metallic heterostructures