Dissipative dynamics at first-order quantum transitions
Abstract
We investigate the effects of dissipation on the quantum dynamics of many-body systems at quantum transitions, especially considering those of the first order. This issue is studied within the paradigmatic one-dimensional quantum Ising model. We analyze the out-of-equilibrium dynamics arising from quenches of the Hamiltonian parameters and dissipative mechanisms modeled by a Lindblad master equation, with either local or global spin operators acting as dissipative operators. Analogously to what happens at continuous quantum transitions, we observe a regime where the system develops a nontrivial dynamic scaling behavior, which is realized when the dissipation parameter (globally controlling the decay rate of the dissipation within the Lindblad framework) scales as the energy difference of the lowest levels of the Hamiltonian, i.e., . However, unlike continuous quantum transitions where is power-law suppressed, at first-order quantum transitions is exponentially suppressed with increasing the system size (provided the boundary conditions do not favor any particular phase).
Cite
@article{arxiv.2009.11158,
title = {Dissipative dynamics at first-order quantum transitions},
author = {Giovanni Di Meglio and Davide Rossini and Ettore Vicari},
journal= {arXiv preprint arXiv:2009.11158},
year = {2020}
}
Comments
14 pages, 7 figures. Final version