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Coherent charge and spin oscillations induced by local quenches in nanowires with spin-orbit coupling

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arxiv 1909.01574 v1 pith:QOMXPND7 submitted 2019-09-04 cond-mat.mes-hall cond-mat.other

Coherent charge and spin oscillations induced by local quenches in nanowires with spin-orbit coupling

classification cond-mat.mes-hall cond-mat.other
keywords nanowirespotentialattractivecoherenteffectoscillationschargecontinuum
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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When a local and attractive potential is quenched in a nanowire, the spectrum changes its topology from a purely continuum to a continuum and discrete portion. We show that, under appropriate conditions, this quench leads to stable coherent oscillations in the observables time evolution. In particular, we demonstrate that ballistic nanowires with spin-orbit coupling (SOC) exposed to a uniform magnetic field are especially suitable to observe this effect. Indeed, while in ordinary nanowires the effect occurs only if the strength $U_0$ of the attractive potential is sufficiently strong, even a weak value of $U_0$ is sufficient in SOC nanowires. Furthermore, in these systems coherent oscillations in the spin sector can be generated and controlled electrically by quenching the gate voltage acting on the charge sector. We interpret the origin of this phenomenon, analyze the effect of variation of the chemical potential and the switching time of the quenched attractive potential, and address possible implementation schemes.

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