We consider quantum quenches to the sinh-Gordon integrable quantum field theory from a particular class of initial states. Our analysis includes the case of mass and interaction quenches starting from a noninteracting theory. By means of the recently developed quench action method, we fully characterize the stationary state reached at long times after the quench in terms of the corresponding rapidity distribution. We also provide exact results for the expectation values of arbitrary vertex operators in the postquench stationary state by proposing a formula based on the analogy with the standard thermodynamic Bethe ansatz. Finally, we comment on the behavior of the post-quench stationary state under the mapping between the sinh-Gordon field theory and the one-dimensional LiebLiniger model.
Bruno Bertini, Lorenzo Piroli, Pasquale Calabrese (2016). Quantum quenches in the sinh-Gordon model: Steady state and one-point correlation functions. JOURNAL OF STATISTICAL MECHANICS: THEORY AND EXPERIMENT, 2016(6), 063102-1-063102-30 [10.1088/1742-5468/2016/06/063102].
Quantum quenches in the sinh-Gordon model: Steady state and one-point correlation functions
Lorenzo Piroli;
2016
Abstract
We consider quantum quenches to the sinh-Gordon integrable quantum field theory from a particular class of initial states. Our analysis includes the case of mass and interaction quenches starting from a noninteracting theory. By means of the recently developed quench action method, we fully characterize the stationary state reached at long times after the quench in terms of the corresponding rapidity distribution. We also provide exact results for the expectation values of arbitrary vertex operators in the postquench stationary state by proposing a formula based on the analogy with the standard thermodynamic Bethe ansatz. Finally, we comment on the behavior of the post-quench stationary state under the mapping between the sinh-Gordon field theory and the one-dimensional LiebLiniger model.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
