Order and Chaos in the \(SU(2)\) Matrix Model: Ergodicity and Classical Phases

We study the classical non-linear dynamics of the \(SU(2)\) Yang-Mills matrix model introduced in [1] as a low-energy approximation to two-color QCD. Restricting to the spin-0 sector of the model, we unearth an unexpected tetrahedral symmetry, which endows the dynamics with an extraordinarily rich structure. Amongst other things, we find that the spin-0 sector contains co-existing chaotic sub-sectors as well as nested chaotic basins, and displays alternation between regular and chaotic dynamics as energy is varied. The symmetries also grant us a considerable amount of analytic control which allows us to make several quantitative observations. Next, by noting that several features of the model have natural thermodynamic interpretations, we switch from our original chaos-theoretic viewpoint to a more statistical perspective. By so doing, we see that the classical spin-0 sector has a rich phase structure, arising from ergodicity breaking, which we investigate in depth. Surprisingly, we find that many of these classical phases display numerous similarities to previously discovered quantum phases of the spin-0 sector [2], and we explore these similarities in a heuristic fashion.