Deterministic switching of a perpendicularly polarized magnet using unconventional spin-orbit torques in WTe 2 .
I-Hsuan KaoRyan MuzzioHantao ZhangMenglin ZhuJacob GobboSean YuanDaniel WeberRahul RaoJiahan LiJames H EdgarJoshua E GoldbergerJiaqiang YanDavid G MandrusJinwoo HwangRan ChengJyoti KatochSimranjeet SinghPublished in: Nature materials (2022)
Spin-orbit torque (SOT)-driven deterministic control of the magnetic state of a ferromagnet with perpendicular magnetic anisotropy is key to next-generation spintronic applications including non-volatile, ultrafast and energy-efficient data-storage devices. However, field-free deterministic switching of perpendicular magnetization remains a challenge because it requires an out-of-plane antidamping torque, which is not allowed in conventional spin-source materials such as heavy metals and topological insulators due to the system's symmetry. The exploitation of low-crystal symmetries in emergent quantum materials offers a unique approach to achieve SOTs with unconventional forms. Here we report an experimental realization of field-free deterministic magnetic switching of a perpendicularly polarized van der Waals magnet employing an out-of-plane antidamping SOT generated in layered WTe 2 , a quantum material with a low-symmetry crystal structure. Our numerical simulations suggest that the out-of-plane antidamping torque in WTe 2 is essential to explain the observed magnetization switching.
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