Hamiltonian Dynamics of a Sum of Interacting Random Matrices

Abstract

In ergodic quantum systems, physical observables have a non-relaxing component if they "overlap" with a conserved quantity. In interacting microscopic models, how to isolate the non-relaxing component is unclear. We compute exact dynamical correlators governed by a Hamiltonian composed of two large interacting random matrices, H=A+B. We analytically obtain the late-time value of A(t) A(0) ; this quantifies the non-relaxing part of the observable A. The relaxation to this value is governed by a power-law determined by the spectrum of the Hamiltonian H, independent of the observable A. For Gaussian matrices, we further compute out-of-time-ordered-correlators (OTOCs) and find that the existence of a non-relaxing part of A leads to modifications of the late time values and exponents. Our results follow from exact resummation of a diagrammatic expansion and hyperoperator techniques.