采用新型高阻生长和迁移势垒层的高自旋霍尔角掺杂BiSbX拓扑绝缘体

B. York, P. Hai, Q. Le, C. Hwang, S. Okamura, M. Gribelyuk, X. Xu, K. Nguyen, H. Ho, J. Sasaki, X. Liu, S. Le, M. Ho, H. Takano, R. Simmons
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引用次数: 0

摘要

我们使用掺杂BiSbX TI材料作为SOT层,制作了简单的底部SOT膜堆,具有新型的高电阻成核/生长和迁移阻挡层。薄的缓冲层产生非常强的纤维轴(012)织构(摇摆曲线~ 7度)。应用。FM层和SOT层之间的迁移屏障显著减少了Bi、Sb从SOT中迁移出来,以及FM层的电分流。种子层和盖层的电阻率很高(~ 250 μ m-cm),薄迁移层和成核/生长层的电阻率也很高(~ > 300 μ m-cm)。迁移阻挡层对于减少SOT和调频层之间的混合、降低SOT表面粗糙度、锐化SOT-层间界面以及减少调频分流效应至关重要。从图1所示的简单薄膜堆中制备了20umX60um (WxL)的交叉霍尔条纹图案。非常高的SHA值约为24(见图)。4 b。和5b.)在两种不同掺杂的BiSbX SOT材料上测量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
High Spin Hall Angle doped BiSbX Topological Insulators using novel high resistive growth and migration barrier layers
We have fabricated simple bottom-SOT film stacks using doped BiSbX TI materials as the SOT layer with novel high resistance nucleation/growth and migration barrier layers. The thin buffer layer produces a very strong fiber axis (012) texture (rocking curve ~ 7 degs. FWHM). The migration barrier between the FM and The SOT layers significantly reduces both Bi,Sb migration out of the SOT and electrical shunting across the FM. The seed and capping layers have high resistivities (~ 250 uohm-cm), as do the thin migration and nucleation/growth layers (resistivities ~ > 300 uohm-cm). The migration barrier layer is critical to reduce intermixing between SOT and FM layer reducing SOT surface roughness, sharpening the SOT-interlayer interface, and to reduce FM shunting effects. Cross Hall-bar patterns 20umX60um (WxL) were fabricated from the simple film stacks shown schematically in figure 1. Very high SHA values of about 24 (see figs. 4b., and 5b.) were measured on two differently doped BiSbX SOT materials.
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