Your search keyword '"Scopa, Stefano"' showing total 5 results

1. Scaling of fronts and entanglement spreading during a domain wall melting.

Author

Scopa, Stefano and Karevski, Dragi

Subjects

*CONFORMAL field theory, *SEMICLASSICAL limits, *EULER equations, *PHASE space, *QUANTUM fluctuations, *COMPUTABLE functions, *CONSERVED quantity

Abstract

We revisit the out-of-equilibrium physics arising during the unitary evolution of a one-dimensional XXZ spin chain initially prepared in a domain wall state | ψ 0 ⟩ = | ⋯ ↑ ↑ ↓ ↓ ⋯ ⟩ . In absence of interactions, we review the exact lattice calculation of several conserved quantities, including e.g. the magnetization and the spin current profiles. At large distances x and times t, we show how these quantities allow for a ballistic scaling behavior in terms of the scaling variable ζ = x / t , with exactly computable scaling functions. In such a limit of large space-time scales, we show that the asymptotic behavior of the system is suitably captured by the local occupation function of spinless fermionic modes, whose semi-classical evolution in phase space is given by a Euler hydrodynamic equation. Similarly, analytical results for the asymptotic fronts dynamics are obtained for the interacting chain via Generalized Hydrodynamics. In the last part of the work, we include large-scale quantum fluctuations on top of the semi-classical hydrodynamic background in the form of a conformal field theory that lives along the evolving Fermi contour. With this procedure, dubbed quantum generalized hydrodynamics, it is possible to obtain exact asymptotic results for the entanglement spreading during the melting dynamics. [ABSTRACT FROM AUTHOR]

Published

2023

2. Entanglement dynamics of a hard-core quantum gas during a Joule expansion.

Author

Ares, Filiberto, Scopa, Stefano, and Wald, Sascha

Subjects

*QUANTUM theory, *QUANTUM gases, *HYDRODYNAMICS

Abstract

We study the entanglement dynamics of a one-dimensional hard-core quantum gas initially confined in a box of size L with saturated density ρ = 1. The gas is suddenly released into a region of size 2 L by moving one of the box edges. We show that the analytic prediction for the entanglement entropy obtained from quantum fluctuating hydrodynamics holds quantitatively true even after several reflections of the gas against the box edges. We further investigate the long time limit t / L ≫ 1 where a Floquet picture of the non-equilibrium dynamics emerges and hydrodynamics eventually breaks down. [ABSTRACT FROM AUTHOR]

Published

2022

3. Exact entanglement growth of a one-dimensional hard-core quantum gas during a free expansion.

Author

Scopa, Stefano, Krajenbrink, Alexandre, Calabrese, Pasquale, and Dubail, Jérôme

Subjects

*QUANTUM gases, *CONFORMAL field theory, *STATISTICAL correlation, *QUANTUM entropy

Abstract

We consider the non-equilibrium dynamics of the entanglement entropy of a one-dimensional quantum gas of hard-core particles, initially confined in a box potential at zero temperature. At t = 0 the right edge of the box is suddenly released and the system is let free to expand. During this expansion, the initially correlated region propagates with a non-homogeneous profile, leading to the growth of entanglement entropy. This setting is investigated in the hydrodynamic regime, with tools stemming from semi-classical Wigner function approach and with recent developments of quantum fluctuating hydrodynamics. Within this framework, the entanglement entropy can be associated to a correlation function of chiral twist-fields of the conformal field theory that lives along the Fermi contour and it can be exactly determined. Our predictions for the entanglement evolution are found in agreement with and generalize previous results in literature based on numerical calculations and heuristic arguments. [ABSTRACT FROM AUTHOR]

Published

2021

4. Determinant formula for the field form factor in the anyonic Lieb–Liniger model.

Author

Piroli, Lorenzo, Scopa, Stefano, and Calabrese, Pasquale

Subjects

*NUMERICAL calculations, *CIRCULANT matrices

Abstract

We derive an exact formula for the field form factor in the anyonic Lieb–Liniger model, valid for arbitrary values of the interaction c, anyonic parameter κ, and number of particles N. Analogously to the bosonic case, the form factor is expressed in terms of the determinant of an N × N matrix, whose elements are rational functions of the Bethe quasimomenta but explicitly depend on κ. The formula is efficient to evaluate, and provide an essential ingredient for several numerical and analytical calculations. Its derivation consists of three steps. First, we show that the anyonic form factor is equal to the bosonic one between two special off-shell Bethe states, in the standard Lieb–Liniger model. Second, we characterize its analytic properties and provide a set of conditions that uniquely specify it. Finally, we show that our determinant formula satisfies these conditions. [ABSTRACT FROM AUTHOR]

Published

2020

5. One-particle density matrix of a trapped Lieb–Liniger anyonic gas.

Author

Scopa, Stefano, Piroli, Lorenzo, and Calabrese, Pasquale

Published

2020