Quantum transport theory for nanostructures with Rashba spin-orbital interaction
Qing-feng Sun,Jian Wang,Hong Guo +2 more
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TLDR
In this article, a general theory for analyzing quantum transport through devices in the metal-QD-metal configuration where QD is a quantum dot or the device-scattering region which contains Rashba spin-orbital and electron-electron interactions is presented.Abstract:
We report on a general theory for analyzing quantum transport through devices in the metal-QD-metal configuration where QD is a quantum dot or the device-scattering region which contains Rashba spin-orbital and electron-electron interactions. The metal leads may or may not be ferromagnetic, and they are assumed to weakly couple to the QD region. Our theory is formulated by second quantizing the Rashba spin-orbital interaction in spectral space (instead of real space), and quantum transport is then analyzed within the Keldysh nonequilibrium Green's function formalism. The Rashba interaction causes two main effects to the Hamiltonian: (i) it gives rise to an extra spin-dependent phase factor in the coupling matrix elements between the leads and the QD, and (ii) it gives rise to an interlevel spin-flip term, but forbids any intralevel spin flips. Our formalism provides a starting point for analyzing many quantum transport issues where spin-orbital effects are important. As an example, we investigate the transport properties of a Aharnov-Bohm ring in which a QD having a Rashba spin-orbital and electron-electron interactions is located in one arm of the ring. A substantial spin-polarized conductance or current emerges in this device due to the combined effect of a magnetic flux and the Rashba interaction. The direction and strength of the spin polarization are shown to be controllable by both the magnetic flux and a gate voltage.read more
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Thermoelectric and Interference Effects in a Kondo-Correlated Quantum Dot with Rashba Spin-Orbit Coupling
TL;DR: In this paper, a strongly correlated quantum dot coupled to two ferromagnetic leads is investigated theoretically by means of the slave boson technique, where the dot is coupled to the leads both symmetrically via the spin-conserving tunneling processes and asymmetrically through spin-nonconserving Rashba-induced tunneling terms.
Journal ArticleDOI
Rashba contribution of 2D Dirac–Weyl fermions: beyond ordinary quantum regime
TL;DR: In this paper , the energy levels of Dirac-Weyl fermions in graphene subject to a magnetic field with Rashba contribution in the minimal length situation were studied, and it was shown that the emerging energy spectrum at the high magnetic field limit becomes independent of the Rashba coupling, and the band index of Landau levels.
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Quantum interference and Kondo effects in an Aharonov–Bohm–Casher interferometer containing a laterally coupled double quantum dot
TL;DR: In this paper, the authors theoretically investigate spin-dependent electron transport through an Aharonov-Bohm-Casher interferometer containing a laterally coupled double quantum dot.
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Linear conductance and tunnel magnetoresistance in a rashba quantum dot ring coupled to ferromagnetic leads
Feng Chi,Ling Huang,Jia Zhao +2 more
TL;DR: In this article, the authors investigated spin-dependent electronic transport through a quantum ring with a quantum dot (QD) inserted in one of its arms, where the ring is connected to external ferromagnetic electrodes and there is Rashba spin-orbit interaction (SOI) in the QD.
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Roles of quantum interference in modulating the spin-polarized transport induced by single-helical molecules
TL;DR: In this paper, the authors investigated the spin-polarized transport through the systems with protein-like single-helical molecules, and they showed that the spin polarization property and efficiency tightly depend on the geometries of the systems of one-and two-lead molecules.
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