Universal Aspects of High-Temperature Relaxation Dynamics in Random Spin Models

Abstract

Universality is a crucial concept in modern physics, allowing us to capture the essential features of a system's behavior using a small set of parameters. In this work, we unveil universal spin relaxation dynamics in anisotropic random Heisenberg models with infinite-range interactions at high temperatures. Starting from a polarized state, the total magnetization can relax monotonically or decay with long-lived oscillations, determined by the sign of a universal single function A=-12+22-423+32. Here (1,3,3) characterizes the anisotropy of the Heisenberg interaction. Furthermore, the oscillation shows up only for A>0, with frequency A. To validate our theory, we compare it to numerical simulations by solving the Kadanoff-Baym (KB) equation with a melon diagram approximation and the exact diagonalization (ED). The results show our theoretical prediction works in both cases, regardless of a small system size N=8 in ED simulations. Our study sheds light on the universal aspect of quantum many-body dynamics beyond low energy limit.