Out-of-equilibrium dynamics across the first-order quantum transitions of one-dimensional quantum Ising models

Abstract

We study the out-of-equilibrium dynamics of one-dimensional quantum Ising models in a transverse field g, driven by a time-dependent longitudinal field h across their magnetic first-order quantum transition at h=0, for sufficiently small values of |g|. We consider nearest-neighbor Ising chains of size L with periodic boundary conditions. We focus on the out-of-equilibrium behavior arising from Kibble-Zurek protocols, in which h is varied linearly in time with time scale ts, i.e., h(t)=t/ts. The system starts from the ground state at hi h(ti)<0, where the longitudinal magnetization M is negative. Then it evolves unitarily up to positive values of h(t), where M(t) becomes eventually positive. We identify several scaling regimes characterized by a nontrivial interplay between the size L and the time scale ts, which can be observed when the system is close to one of the many avoided level crossings that occur for h 0. In the L∞ limit, all these crossings approach h=0+, making the study of the thermodynamic limit, defined as the limit L∞ keeping t and ts constant, problematic. We study such limit numerically, by first determining the large-L quantum evolution at fixed ts, and then analyzing its behavior with increasing ts. Our analysis shows that the system switches from the initial state with M<0 to a positively magnetized state at h = h*(ts)>0, where h*(ts) decreases with increasing ts, apparently as h* 1/ ts. This suggests the existence of a scaling behavior in terms of the rescaled time = t ts/ts. The numerical results also show that the system converges to a nontrivial stationary state in the large-t limit, characterized by an energy significantly larger than that of the corresponding homogeneously magnetized ground state.

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