Ergodic properties of a generic non-integrable quantum many-body system in thermodynamic limit
Abstract
We study a generic but simple non-integrable quantum many-body system of locally interacting particles, namely a kicked t-V model of spinless fermions on 1-dim lattice (equivalent to a kicked Heisenberg XX-Z chain of 1/2 spins). Statistical properties of dynamics (quantum ergodicity and quantum mixing) and the nature of quantum transport in thermodynamic limit are considered as the kick parameters (which control the degree of non-integrability) are varied. We find and demonstrate ballistic transport and non-ergodic, non-mixing dynamics (implying infinite conductivity at all temperatures) in the integrable regime of zero or very small kick parameters, and more generally and important, also in non-integrable regime of intermediate values of kicked parameters, whereas only for sufficiently large kick parameters we recover quantum ergodicity and mixing implying normal (diffusive) transport. We propose an order parameter (charge stiffness D) which controls the phase transition from non-mixing/non-ergodic dynamics (ordered phase, D>0) to mixing/ergodic dynamics (disordered phase, D=0) in the thermodynamic limit. Furthermore, we find exponential decay of time-correlation function in the regime of mixing dynamics. The results are obtained consistently within three different numerical and analytical approaches: (i) time evolution of a finite system and direct computation of time correlation functions, (ii) full diagonalization of finite systems and statistical analysis of stationary data, and (iii) algebraic construction of quantum invariants of motion of an infinite system, in particular the time averaged observables.
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