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| Hauptseite > Publikationsdatenbank > Lifetime of spin-orbit induced spin textures in a semiconductor heterostructure probed by quantum corrections to conductivity |
| Hauptseite > Publikationsdatenbank > Lifetime of spin-orbit induced spin textures in a semiconductor heterostructure probed by quantum corrections to conductivity |
| Journal Article | FZJ-2023-00003 |
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2022
APS
College Park, MD
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Please use a persistent id in citations: http://hdl.handle.net/2128/33358 doi:10.1103/PhysRevResearch.4.043217
Abstract: The persistent spin helix (PSH) is the stable spin state protected by SU(2) spin-rotation symmetry. Long-livedspin textures, referred to as helical and homogeneous spin modes, emerge as a result of this symmetry. Thesetextures are potential candidates for the development of quantum and topological phenomena as well as information carriers in semiconductors. To this end, revealing the lifetime of all spin modes is of great importance. Weexperimentally reveal the lifetime of both helical and homogeneous spin modes in the vicinity of the PSH stateby fully electrical means through quantum corrections to the conductivity. In a (001)-grown GaAs/AlGaAs twodimensional electron gas, we measure the weak antilocalization in the condition where Rashba and Dresselhausspin-orbit (SO) interactions coexist. According to the latest theory on magnetoconductance [Kammermeier et al.,Phys. Rev. B 104, 235430 (2021)], the Cooperon triplet mode in the quantum corrections can be decoupledinto helical and homogeneous spin modes in the vicinity of the PSH state, which allows each mode lifetimeto be determined from the quantum interference effect. By using a real-space simulation in tandem with theexperiment, we were able to simultaneously evaluate the relaxation rates of the two spin modes. Our results showthat the ratio of Rashba and Dresselhaus SO coefficients is modulated by the top gate and that this quadraticallychanges the relaxation rates of the helical and homogeneous spin modes, which is consistent with theoreticalpredictions. These findings pave the way for exploring electron spin textures in various bandgap materials fromsemiconductors to metals.
Keyword(s): Information and Communication (1st) ; Condensed Matter Physics (2nd)
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