Punctuated chaos and the unpredictability of the Galactic center S-star orbital evolution

Abstract

We investigate the chaotic behavior of the S-star cluster in the Galactic center using precise N-body calculations, free from round-off or discretization errors. Our findings reveal that chaos among the Galactic center S-stars arises from close encounters, particularly among pairs and near the massive central body. These encounters induce perturbations, causing sudden changes in the orbital energies of the interacting stars. Consequently, neighboring solutions experience roughly exponential growth in separation. We propose a theory of "punctuated chaos" that describes the S-star cluster's chaotic behavior. This phenomenon results from nearly linear growth in the separation between neighboring orbits after repeated finite perturbations. Each participating star's orbit experiences discrete, abrupt changes in energy due to the perturbations. The cumulative effect of these events is further amplified by the steady drift in orbital phase. In the Galactic center, perturbations originate from coincidental encounters occurring within a distance of 100\,au between at least two stars (in some cases, three stars). Our model satisfactorily explains the observed exponential growth in the 27 S-star cluster. We determine that the S-star system has a Lyapunov time scale of approximately 462 +/-74 years. For the coming millennium, chaos in the S-star cluster will be driven mainly by a few of the closest orbiting stars: S2, S5, S6, S8, S9, S14, S18, S31, S21, S24, S27, S29, and S38.