Abstract
Topological insulators with spin-momentum-locked topological surface states are expected to exhibit a giant spin-orbit torque in the topological insulator/ferromagnet systems. To date, the topological insulator spin-orbit torque-driven magnetization switching is solely reported in a Cr-doped topological insulator at 1.9 K. Here we directly show giant spin-orbit torque-driven magnetization switching in a Bi2Se3/NiFe heterostructure at room temperature captured using a magneto-optic Kerr effect microscope. We identify a large charge-to-spin conversion efficiency of ~1–1.75 in the thin Bi2Se3 films, where the topological surface states are dominant. In addition, we find the current density required for the magnetization switching is extremely low, ~6 × 105 A cm–2, which is one to two orders of magnitude smaller than that with heavy metals. Our demonstration of room temperature magnetization switching of a conventional 3d ferromagnet using Bi2Se3 may lead to potential innovations in topological insulator-based spintronic applications.
Highlights
Topological insulators with spin-momentum-locked topological surface states are expected to exhibit a giant spin-orbit torque in the topological insulator/ferromagnet systems
Our results suggest that topological insulators (TIs)/FM heterostructure could be a potential candidate for room temperature spintronic devices with ultralow-power dissipation
We find that the current density required for the room temperature spin-orbit torques (SOTs)-induced magnetization switching in Bi2Se3/Py is extremely low at ~6 × 105 A cm–2, which is one to two orders of magnitude smaller than that with heavy metals[23,24,25]
Summary
Topological insulators with spin-momentum-locked topological surface states are expected to exhibit a giant spin-orbit torque in the topological insulator/ferromagnet systems. The SOTs have been studied in topological insulators (TIs)[7,8,9,10,11,12,13,14], which are an emerging state of quantum matter possessing spin-momentum-locked topological surface states (TSS)[15,16,17] This exotic property is supposed to exhibit a large SOT efficiency, which is explored recently by the spin transport methods such as spin-torque ferromagnetic resonance (ST-FMR)[7,8,13], spin pumping[9,10,14,18], and spin tunneling spectroscopy[19,20]. Our results suggest that TI/FM heterostructure could be a potential candidate for room temperature spintronic devices with ultralow-power dissipation
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