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Entanglement dynamics after a quench in Ising field theory: a branch point twist field approach

Olalla A. Castro-AlvaredoDepartment of Mathematics, City, University of London, 10 Northampton Square, London, EC1V 0HB, U.KMáté LencsésInternational Institute of Physics, UFRN, Campos Universitário, Lagoa Nova, Natal, 59078-970, BrazilIstván M. SzécsényiDepartment of Mathematics, City, University of London, 10 Northampton Square, London, EC1V 0HB, U.KJacopo VitiECT, UFRN, Campos Universitário, Lagoa Nova, Natal, 59078-970, Brazil
2019en
ABI

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A bstract We extend the branch point twist field approach for the calculation of entanglement entropies to time-dependent problems in 1+1-dimensional massive quantum field theories. We focus on the simplest example: a mass quench in the Ising field theory from initial mass m 0 to final mass m . The main analytical results are obtained from a perturbative expansion of the twist field one-point function in the post-quench quasi-particle basis. The expected linear growth of the Rényi entropies at large times mt ≫ 1 emerges from a perturbative calculation at second order. We also show that the Rényi and von Neumann entropies, in infinite volume, contain subleading oscillatory contributions of frequency 2 m and amplitude proportional to ( mt ) − 3 / 2 . The oscillatory terms are correctly predicted by an alternative perturbation series, in the pre-quench quasi-particle basis, which we also discuss. A comparison to lattice numerical calculations carried out on an Ising chain in the scaling limit shows very good agreement with the quantum field theory predictions. We also find evidence of clustering of twist field correlators which implies that the entanglement entropies are proportional to the number of subsystem boundary points.

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