Spintronics meets orbitronics: Emergence of orbital angular momentum in solids

Daegeun Jo, Dongwook Go, Gyung-Min Choi, Hyun-Woo Lee
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Abstract

One of the ultimate goals of spintronics is to realize an efficient electrical manipulation of spin for high-speed and low-power nanodevices. A core ingredient for achieving this goal is the relativistic interaction between the electron’s orbital motion and spin, but the properties of the orbital angular momentum itself have remained largely unexplored. However, recent theories and experiments have uncovered that electrons may acquire nonvanishing orbital angular momentum when an external electric field is applied, even without the spin–orbit coupling. These findings have spurred the emergence of a burgeoning field known as orbitronics, which harnesses the orbital angular momentum to manipulate magnetic devices. In this Review, we provide an overview of the recent developments in orbitronics and discuss their implications for spintronics. We then outline future avenues of research at the intersection of spintronics and orbitronics.

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自旋电子学与轨道电子学的结合:固体中轨道角动量的出现
自旋电子学的终极目标之一是实现对自旋的高效电子操控,从而制造出高速、低功耗的纳米器件。实现这一目标的核心要素是电子轨道运动与自旋之间的相对论相互作用,但轨道角动量本身的特性在很大程度上仍未得到探索。然而,最近的理论和实验发现,在施加外部电场时,即使没有自旋轨道耦合,电子也可能获得非消失轨道角动量。这些发现推动了轨道电子学这一新兴领域的出现,该领域利用轨道角动量操纵磁性器件。在这篇综述中,我们将概述轨道电子学的最新发展,并讨论它们对自旋电子学的影响。然后,我们将概述自旋电子学和轨道电子学交叉领域的未来研究方向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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