Microscopic theory of spin Nernst effect

IF 3.7 2区 物理与天体物理 Q1 Physics and Astronomy Physical Review B Pub Date : 2024-11-07 DOI:10.1103/physrevb.110.174411
Junji Fujimoto, Taiki Matsushita, Masao Ogata
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Abstract

We present the microscopic theory of the spin Nernst effect, which is a transverse spin current directly induced by a temperature gradient, employing the linear response theory with Luttinger's gravitational potential method. We consider a generic, noninteracting electron system with randomly distributed impurities and evaluate the spin current response to the gravitational potential. Our theory takes into account a contribution of the local equilibrium current modified by Luttinger's gravitational potential and is thus consistent with the thermodynamic principle that thermal responses should vanish at absolute zero. The Ward-Takahashi identities ensure that the spin Nernst current is well-behaved at low temperatures in any order of the random impurity potentials. Furthermore, we microscopically derive the spin-current version of Mott's formula, which associates the spin Nernst coefficient with the spin Hall conductivity. The spin-current version of the Středa formula is also discussed. To demonstrate these findings, the spin Nernst current of three-dimensional Dirac electrons is computed. Our theory is general and can therefore be extended to interacting electron systems, where Mott's formula no longer holds.
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自旋 Nernst 效应的微观理论
我们介绍了自旋奈恩斯特效应的微观理论,这是一种由温度梯度直接诱导的横向自旋电流,采用的是线性响应理论和卢廷格重力势能法。我们考虑了一个具有随机分布杂质的通用非相互作用电子系统,并评估了自旋电流对引力势的响应。我们的理论考虑了局部平衡电流经卢廷格引力势修正后的贡献,因此符合热力学原理,即热反应应在绝对零度消失。Ward-Takahashi 特性确保了自旋奈恩斯特电流在低温下以随机杂质电势的任何阶次表现良好。此外,我们还从微观上推导出莫特公式的自旋电流版本,它将自旋奈尔斯特系数与自旋霍尔电导率联系在一起。我们还讨论了斯特里达公式的自旋电流版本。为了证明这些发现,我们计算了三维狄拉克电子的自旋能斯特电流。我们的理论具有普遍性,因此可以扩展到莫特公式不再成立的相互作用电子系统。
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来源期刊
Physical Review B
Physical Review B 物理-物理:凝聚态物理
CiteScore
6.70
自引率
32.40%
发文量
0
审稿时长
3.0 months
期刊介绍: Physical Review B (PRB) is the world’s largest dedicated physics journal, publishing approximately 100 new, high-quality papers each week. The most highly cited journal in condensed matter physics, PRB provides outstanding depth and breadth of coverage, combined with unrivaled context and background for ongoing research by scientists worldwide. PRB covers the full range of condensed matter, materials physics, and related subfields, including: -Structure and phase transitions -Ferroelectrics and multiferroics -Disordered systems and alloys -Magnetism -Superconductivity -Electronic structure, photonics, and metamaterials -Semiconductors and mesoscopic systems -Surfaces, nanoscience, and two-dimensional materials -Topological states of matter
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