Nonlinear Orbital and Spin Edelstein Effect in Centrosymmetric Metals
Nonlinear spintronics combines nonlinear dynamics with spintronics, opening up new possibilities beyond linear responses. A recent theoretical work [Xiao et al., Phys. Rev. Lett. 130, 166302 (2023)] predicts the nonlinear generation of spin density [nonlinear spin Edelstein effect (NSEE)] in centros...
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Zusammenfassung: | Nonlinear spintronics combines nonlinear dynamics with spintronics, opening
up new possibilities beyond linear responses. A recent theoretical work [Xiao
et al., Phys. Rev. Lett. 130, 166302 (2023)] predicts the nonlinear generation
of spin density [nonlinear spin Edelstein effect (NSEE)] in centrosymmetric
metals based on symmetry analysis combined with first principle calculation.
However, its microscopic mechanism is limited to a specific set of materials
with local inversion symmetry breaking and is not applicable to general
materials. This paper focuses on the fundamental role of orbital degrees of
freedom for the nonlinear generation in centrosymmetric systems. Using a
combination of tight-binding model and density functional theory calculations,
we demonstrate that nonlinear orbital density can arise independently of
spin-orbit coupling. In contrast, spin density follows through spin-orbit
coupling. We further elucidate the microscopic mechanism responsible for this
phenomenon, which involves the NSEE induced by electric-field-induced orbital
Rashba texture. In addition, we also explore the potential applications of the
nonlinear orbital and spin Edelstein effect for field-free switching of
magnetization. |
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DOI: | 10.48550/arxiv.2310.05113 |