On the Approach to Thermal Equilibrium of Macroscopic Quantum Systems

Abstract

We consider an isolated, macroscopic quantum system. Let H be a micro-canonical "energy shell," i.e., a subspace of the system's Hilbert space spanned by the (finitely) many energy eigenstates with energies between E and E + delta E. The thermal equilibrium macro-state at energy E corresponds to a subspace Heq of H such that dim Heq/dim H is close to 1. We say that a system with state vector psi in H is in thermal equilibrium if psi is "close" to Heq. We show that for "typical" Hamiltonians with given eigenvalues, all initial state vectors psi0 evolve in such a way that psit is in thermal equilibrium for most times t. This result is closely related to von Neumann's quantum ergodic theorem of 1929.