Von Neumann entropy in a Rashba-Dresselhaus nanodot; dynamical electronic spin-orbit entanglement

Safaiee, R.; Golshan, M.M.

doi:10.1140/epjb/e2017-70732-5

Cited by 2 publications

(1 citation statement)

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“…That chaos can enhance spin-orbital entanglement can be argued, heuristically, as follows. The pair of eigenvalues of the spin density matrix can be obtained as λ 1,2 = (1±|𝑃 |)/2, with which the van Neumann entropy can be expressed in terms of the magnitude of 𝑃 as [86]…”

Section: S = −Tr[ ρS Ln ρSmentioning

confidence: 99%

Enhancing von Neumann entropy by chaos in spin–orbit entanglement*

Liu

Chen

et al. 2019

Chinese Phys. B

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For a quantum system with multiple degrees of freedom or subspaces, loss of coherence in a certain subspace is intimately related to the enhancement of entanglement between this subspace and another one. We investigate intra-particle entanglement in two-dimensional mesoscopic systems, where an electron has both spin and orbital degrees of freedom and the interaction between them is enabled by Rashba type of spin–orbit coupling. The geometric shape of the scattering region can be adjusted to produce a continuous spectrum of classical dynamics with different degree of chaos. Focusing on the spin degree of freedom in the weak spin–orbit coupling regime, we find that classical chaos can significantly enhance spin–orbit entanglement at the expense of spin coherence. Our finding that classical chaos can be beneficial to intra-particle entanglement may have potential applications such as enhancing the bandwidth of quantum communications.

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Section: S = −Tr[ ρS Ln ρSmentioning

confidence: 99%