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This research aims to study the dynamics of quantum phase transitions in the lattice Thirring model under nonequilibrium conditions.

February 8, 2026Open Access

Dynamical Quantum Phase Transition and Thermal Equilibrium in the Lattice Thirring Model

Key Points

This research aims to study the dynamics of quantum phase transitions in the lattice Thirring model under nonequilibrium conditions.
Simulated real-time evolution using tensor network methods
Analyzed critical and massive phases
Investigated conditions for dynamical quantum phase transitions
Examined connections to finite temperature phase diagrams
Identified dynamical quantum phase transitions as non-analyticities in the Loschmidt rate
Found that not all quenches across the critical line yield dynamical phase transitions
Discovered a threshold in energy density necessary for dynamical transitions
Established a connection between energy thresholds and regions in the finite temperature phase diagram

Abstract

Using tensor network methods, we simulate the real-time evolution of the lattice Thirring model quenched out of equilibrium in both the critical and massive phases, and study the appearance of dynamical quantum phase transitions, as non-analyticities in the Loschmidt rate. Whereas the presence of a dynamical quantum phase transition in the model does not correspond to quenches across the critical line of the equilibrium phase diagram at zero temperature, we identify a threshold in the energy density of the initial state, necessary for a dynamical quantum phase transition to be present. Moreover, in the case of the gapped quench Hamiltonian, we unveil a connection of this threshold to a transition between different regions in the finite temperature phase diagram.

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Dynamical Quantum Phase Transition and Thermal Equilibrium in the Lattice Thirring Model

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