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Random spin-orbit gates in the system of a Topological insulator and a Quantum dot

The spin-dependent scattering process in a system of topological insulator and quantum dot is studied. The unitary scattering process is viewed as a gate transformation applied to an initial state of two electrons. Due to the randomness imposed through the impurities and alloying-induced effects of band parameters, the formalism of the random unitary gates is implemented. For quantifying entanglement in the system, we explored concurrence and ensemble-averaged Rényi entropy. We found that applied external magnetic field leads to long-range entanglement on the distances much larger than the confinement length. We showed that topological features of itinerant electrons sustain the formation of robust long-distance entanglement, which survives even in the presence of a strong disorder.

preprint2022arXivOpen access
S. WolskiM. InglotC. JasiukiewiczK. A. KouzakovT. MasłowskiT. SzczepańskiS. StagraczyńskiR. StagraczyńskiV. K. DugaevL. Chotorlishvili
cond-mat.mes-hallquant-ph
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Open access10 authors2 topics
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S. WolskiM. InglotC. JasiukiewiczK. A. KouzakovT. MasłowskiT. SzczepańskiS. StagraczyńskiR. StagraczyńskiV. K. DugaevL. Chotorlishvili

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