自旋电子学
磁化
材料科学
矫顽力
电流(流体)
凝聚态物理
显微镜
铁磁性
磁畴壁(磁性)
磁铁
磁力显微镜
磁化动力学
磁畴
磁场
核磁共振
物理
光学
热力学
量子力学
作者
Islay O. Robertson,Cheng Tan,Sam C. Scholten,Alexander J. Healey,Gabriel Abrahams,Guolin Zheng,Aurélien Manchon,Lan Wang,Jean‐Philippe Tetienne
出处
期刊:2D materials
[IOP Publishing]
日期:2022-12-14
卷期号:10 (1): 015023-015023
被引量:12
标识
DOI:10.1088/2053-1583/acab73
摘要
Abstract Van der Waals (vdW) magnets are appealing candidates for realising spintronic devices that exploit current control of magnetization (e.g. switching or domain wall motion), but so far experimental demonstrations have been sparse, in part because of challenges associated with imaging the magnetization in these systems. Widefield nitrogen-vacancy (NV) microscopy allows rapid, quantitative magnetic imaging across entire vdW flakes, ideal for capturing changes in the micromagnetic structure due to an electric current. Here we use a widefield NV microscope to study the effect of current injection in thin flakes (∼10 nm) of the vdW ferromagnet Fe 3 GeTe 2 (FGT). We first observe current-reduced coercivity on an individual domain level, where current injection in FGT causes substantial reduction in the magnetic field required to locally reverse the magnetisation. We then explore the possibility of current-induced domain-wall motion, and provide preliminary evidence for such a motion under relatively low current densities, suggesting the existence of strong current-induced torques in our devices. Our results illustrate the applicability of widefield NV microscopy to imaging spintronic phenomena in vdW magnets, highlight the possibility of efficient magnetization control by direct current injection without assistance from an adjacent conductor, and motivate further investigations of the effect of currents in FGT and other vdW magnets.
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