Ding Shilei, Kang Min-Gu, Legrand William, Gambardella Pietro
Department of Materials, <a href="https://ror.org/05a28rw58">ETH Zurich</a>, 8093 Zurich, Switzerland.
Phys Rev Lett. 2024 Jun 7;132(23):236702. doi: 10.1103/PhysRevLett.132.236702.
Orbital currents have recently emerged as a promising tool to achieve electrical control of the magnetization in thin-film ferromagnets. Efficient orbital-to-spin conversion is required in order to torque the magnetization. Here, we show that the injection of an orbital current in a ferrimagnetic Gd_{y}Co_{100-y} alloy generates strong orbital torques whose sign and magnitude can be tuned by changing the Gd content and temperature. The effective spin-orbital Hall angle reaches up to -0.25 in a Gd_{y}Co_{100-y}/CuO_{x} bilayer compared to +0.03 in Co/CuO_{x} and +0.13 in Gd_{y}Co_{100-y}/Pt. This behavior is attributed to the local orbital-to-spin conversion taking place at the Gd sites, which is about 5 times stronger and of the opposite sign relative to Co. Furthermore, we observe a manyfold increase in the net orbital torque at low temperature, which we attribute to the improved conversion efficiency following the magnetic ordering of the Gd and Co sublattices.
轨道电流最近已成为一种很有前景的工具,可用于实现对薄膜铁磁体中磁化强度的电控制。为了扭转磁化强度,需要高效的轨道到自旋转换。在此,我们表明在亚铁磁体Gd_yCo_100 - y合金中注入轨道电流会产生强大的轨道扭矩,其符号和大小可通过改变Gd含量和温度来调节。与Co/CuO_x中为 +0.03以及Gd_yCo_100 - y/Pt中为 +0.13相比,在Gd_yCo_100 - y/CuO_x双层中有效自旋 - 轨道霍尔角高达 -0.25。这种行为归因于在Gd位点发生的局部轨道到自旋转换,其强度比Co大约强5倍且符号相反。此外,我们观察到在低温下净轨道扭矩增加了许多倍,我们将其归因于Gd和Co亚晶格磁有序后转换效率的提高。
