Quantum thermalization and average entropy of a subsystem

Abstract

Page's seminal result on the average von Neumann (VN) entropy does not immediately apply to realistic many-body systems which are restricted to physically relevant smaller subspaces. We investigate here the VN entropy averaged over the pure states in the subspace HE corresponding to a narrow energy shell centered at energy E. We find that the average entropy is S1 d1, where d1 represents first subsystem's effective number of states relevant to the energy scale E. If dE = (HE) and D (D1) is the Hilbert space dimension of the full system (first subsystem), we estimate that d1 D1γ, where γ = (dE) / (D) for nonintegrable (chaotic) systems and γ < (dE) / (D) for integrable systems. This result can be reinterpreted as a volume-law of entropy, where the volume-law coefficient depends on the density-of-states for nonintegrable systems, and remains below the maximal possible value for integrable systems. We numerically analyze a spin model to substantiate our main results.