Quench Dynamics of Topological Maximally-Entangled States

Abstract

We investigate the quench dynamics of the one-particle entanglement spectra (OPES) for systems with topologically nontrivial phases. By using dimerized chains as an example, it is demonstrated that the evolution of OPES for the quenched bi-partite systems is governed by an effective Hamiltonian which is characterized by a pseudo spin in a time-dependent pseudo magnetic field S(k,t). The existence and evolution of the topological maximally-entangled edge states are determined by the winding number of S(k,t) in the k-space. In particular, the maximally-entangled edge states survive only if nontrivial Berry phases are induced by the winding of S(k,t). In the infinite time limit the equilibrium OPES can be determined by an effective time-independent pseudo magnetic field Seff(k). Furthermore, when maximally-entangled edge states are unstable, they are destroyed by quasiparticles within a characteristic timescale in proportional to the system size.