Please use this identifier to cite or link to this item: http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/5452
Title: Entanglement transitions induced by large deviations
Authors: BHOSALE, UDAYSINH T.
Dept. of Physics
Keywords: Statistical Theory
Energy Levels
Average Entropy
Dirac Operator
Eigenvalue
State
2017
Issue Date: Dec-2017
Publisher: American Physical Society
Citation: Physical Review E, 96(6).
Abstract: The probability of large deviations of the smallest Schmidt eigenvalue for random pure states of bipartite systems, denoted as A and B, is computed analytically using a Coulomb gas method. It is shown that this probability, for large N, goes as exp[−βN2Φ(ζ)], where the parameter β is the Dyson index of the ensemble, ζ is the large deviation parameter, while the rate function Φ(ζ) is calculated exactly. Corresponding equilibrium Coulomb charge density is derived for its large deviations. Effects of the large deviations of the extreme (largest and smallest) Schmidt eigenvalues on the bipartite entanglement are studied using the von Neumann entropy. Effect of these deviations is also studied on the entanglement between subsystems 1 and 2, obtained by further partitioning the subsystem A, using the properties of the density matrix's partial transpose ρ Γ12. The density of states of ρΓ12 is found to be close to the Wigner's semicircle law with these large deviations. The entanglement properties are captured very well by a simple random matrix model for the partial transpose. The model predicts the entanglement transition across a critical large deviation parameter ζ. Log negativity is used to quantify the entanglement between subsystems 1 and 2. Analytical formulas for it are derived using the simple model. Numerical simulations are in excellent agreement with the analytical results.
URI: http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/5452
https://doi.org/10.1103/PhysRevE.96.062149
ISSN: 2470-0045
2470-0053
Appears in Collections:JOURNAL ARTICLES

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