A theory of nonequilibrium steady states in quantum chaotic systems

Abstract

Nonequilibrium steady state (NESS) is a quasistationary state, in which exist currents that continuously produce entropy, but the local observables are stationary everywhere. We propose a theory of NESS under the framework of quantum chaos. In an isolated quantum system, there exist some initial states for which the thermodynamic limit and the long-time limit are noncommutative. The density matrix of these states displays a universal structure. Suppose that α and β are different eigenstates of the Hamiltonian with energies Eα and Eβ, respectively. <α| |β> behaves as a random number which approximately follows the Laplace distribution with zero mean. In thermodynamic limit, the variance of <α| |β> is a smooth function of |Eα-Eβ|, scaling as 1/(Eα-Eβ)2 in the limit |Eα-Eβ| 0. If and only if this scaling law is obeyed, the initial state evolves into NESS in the long time limit. We present numerical evidence of our hypothesis in a few chaotic models. Furthermore, we find that our hypothesis implies the eigenstate thermalization hypothesis (ETH) in a bipartite system.