Xiong Xu, J. X. Lv, Y. Wang, Min Li, Zhe Wang, Hui Wang
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引用次数: 0
摘要
自旋霍尔效应(SHE)为实现基于自旋的记录和信息处理的有利功能提供了一种有前途的解决方案。在这项工作中,我们对组成为ZXM3的反钙钛矿化合物的自旋霍尔电导率(SHC)进行了高通量计算,其中Z是非金属,X是金属,M是铂族金属。从一个超过4500个结构的初始数据库中,我们筛选了295个结构稳定的化合物,并确定了24个固有SHC超过500 (h /e) (Ω - 1 cm - 1)的化合物。我们揭示了在费米能级附近,自旋轨道耦合引起的能量分裂对SHC有很强的依赖性。此外,可以通过适当掺杂电子或空穴来调节SHCs。本工作建立了反钙钛矿中SHC的高通量数据库,这对设计未来的电子和自旋电子器件至关重要。
High-throughput calculation of large spin Hall conductivity in heavy-metal-based antiperovskite compounds
Spin Hall effect (SHE) provides a promising solution to the realization of advantageous functionalities for spin-based recording and information processing. In this work, we conduct high-throughput calculations on the spin Hall conductivity (SHC) of antiperovskite compounds with the composition ZXM3, where Z is a nonmetal, X is a metal, and M is a platinum group metal. From an initial database over 4500 structures, we screen 295 structurally stable compounds and identify 24 compounds with intrinsic SHC exceeding 500 (ℏ/e) (Ω⁻1 cm⁻1). We reveal a strong dependence of SHC on spin-orbit coupling-induced energy splitting near the Fermi level. In addition, SHCs can be regulated through proper doping of electrons or holes. The present work establishes high-throughput database of SHC in antiperovskites which is crucial for designing future electric and spintronic devices.
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