Spin‐Orbit Torque Switching of a Nearly Compensated Ferrimagnet by Topological Surface States Article Swipe

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Ferrimagnetism Materials science Condensed matter physics Spin (aerodynamics) Surface states Spintronics Surface (topology) Torque Topological insulator Topology (electrical circuits) Ferromagnetism Quantum mechanics Physics Geometry Magnetization Magnetic field Thermodynamics Mathematics Combinatorics

Hao Wu , Yong Xu , Peng Deng , Quanjun Pan , Seyed Armin Razavi , Kin Wong , Li Huang , Bingqian Dai , Qiming Shao , Guoqiang Yu , Xingguo Han , Juan‐Carlos Rojas‐Sánchez , S. Mangin , Kang L. Wang ·

YOU? · · 2019 · Open Access · · DOI: https://doi.org/10.1002/adma.201901681 · OA: W2958980164

Utilizing spin‐orbit torque (SOT) to switch a magnetic moment provides a promising route for low‐power‐dissipation spintronic devices. Here, the SOT switching of a nearly compensated ferrimagnet Gd x (FeCo) 1− x by the topological insulator [Bi 2 Se 3 and (BiSb) 2 Te 3 ] is investigated at room temperature. The switching current density of (BiSb) 2 Te 3 (1.20 × 10 5 A cm −2 ) is more than one order of magnitude smaller than that in conventional heavy‐metal‐based structures, which indicates the ultrahigh efficiency of charge‐spin conversion (>1) in topological surface states. By tuning the net magnetic moment of Gd x (FeCo) 1− x via changing the composition, the SOT efficiency has a significant enhancement (6.5 times) near the magnetic compensation point, and at the same time the switching speed can be as fast as several picoseconds. Combining the topological surface states and the nearly compensated ferrimagnets provides a promising route for practical energy‐efficient and high‐speed spintronic devices.