179 research outputs found

    Nonequilibrium Keldysh Formalism for Interacting Leads -- Application to Quantum Dot Transport Driven by Spin Bias

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    The conductance through a mesoscopic system of interacting electrons coupled to two adjacent leads is conventionally derived via the Keldysh nonequilibrium Green's function technique, in the limit of noninteracting leads [see Y. Meir \emph{et al.}, Phys. Rev. Lett. \textbf{68}, 2512 (1991)]. We extend the standard formalism to cater for a quantum dot system with Coulombic interactions between the quantum dot and the leads. The general current expression is obtained by considering the equation of motion of the time-ordered Green's function of the system. The nonequilibrium effects of the interacting leads are then incorporated by determining the contour-ordered Green's function over the Keldysh loop and applying Langreth's theorem. The dot-lead interactions significantly increase the height of the Kondo peaks in density of states of the quantum dot. This translates into two Kondo peaks in the spin differential conductance when the magnitude of the spin bias equals that of the Zeeman splitting. There also exists a plateau in the charge differential conductance due to the combined effect of spin bias and the Zeeman splitting. The low-bias conductance plateau with sharp edges is also a characteristic of the Kondo effect. The conductance plateau disappears for the case of asymmetric dot-lead interaction.Comment: 11 pages, 3 figures, accepted by Annals of Physic

    Topological spin-Hall current in waveguided zinc-blende semiconductors with Dresselhaus spin-orbit coupling

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    We describe an intrinsic spin-Hall effect in nn-type bulk zinc-blende semiconductors with topological origin. When electron transport is confined to a waveguide structure, and the applied electric field is such that the spins of electrons remain as eigenstates of the Dresselhaus spin-orbit field with negligible subband mixing, a gauge structure appears in the momentum space of the system. In particular, the momentum space exhibits a non-trivial Berry curvature which affects the transverse motion of electrons anisotropically in spin, thereby producing a finite spin-Hall effect. The effect should be detectable using standard techniques in the literature such as Kerr rotation, and be readily distinguishable from other mechanisms of the spin-Hall effect.Comment: 6 pages, 3 figure

    Coulomb blockade effects on magnetoresistance of granular magnetic media

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    10.1063/1.1450847Journal of Applied Physics9110 I7628-7630JAPI

    Tunneling magnetotransport in nanogranular-in-gap structure

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    10.1109/TMAG.2002.803202IEEE Transactions on Magnetics385 I2613-2615IEMG

    Thermal dependence of magnetotransport in nanogranular magnetic media

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    10.1063/1.1544111Journal of Applied Physics9310 38050-8052JAPI

    Magnetoresistance modulation in single-electron transistors

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    Digests of the Intermag ConferenceGD08-DICO

    Generalized diffusive spin transport theory in magnetic multilayer structures

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    INTERMAG ASIA 2005: Digests of the IEEE International Magnetics Conference310

    Spin filtering in a two-dimensional electron gas device with asymmetric spatially spread magnetic-electric barriers

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    10.1063/1.1835568Journal of Applied Physics972-JAPI

    Bit isolation in periodic antidot arrays using transverse applied fields

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    10.1063/1.1557394Journal of Applied Physics9310 27053-7055JAPI

    Micromagnetic study of switching in ring-shaped spin valve structures

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    10.1109/TMAG.2004.832379IEEE Transactions on Magnetics404 II2122-2124IEMG
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