Random-Matrix Model for Thermalization

Abstract

An isolated quantum system is said to thermalize if Tr (A (t)) Tr (A eq) for time t ∞. Here (t) is the time-dependent density matrix of the system, eq is the time-independent density matrix that describes statistical equilibrium, and A is a Hermitean operator standing for an observable. We show that for a system governed by a random-matrix Hamiltonian (a member of the time-reversal invariant Gaussian Orthogonal Ensemble (GOE) of random matrices of dimension N), all functions Tr (A (t)) in the ensemble thermalize: For N ∞ every such function tends to the value Tr (A eq(∞)) + Tr (A (0)) g2(t). Here eq(∞) is the equilibrium density matrix at infinite temperature. The oscillatory function g(t) is the Fourier transform of the average GOE level density and falls off as 1 / |t| for large t. With g(t) = g(-t), thermalization is symmetric in time. Analogous results, including the symmetry in time of thermalization, are derived for the time-reversal non-invariant Gaussian Unitary Ensemble (GUE) of random matrices. Comparison with the ``eigenstate thermalization hypothesis'' of Ref.~Sre99 shows overall agreement but raises significant questions.

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