Circular orbits and chaos bound in slow-rotating curved acoustic black holes

In recent years, the incorporation of acoustic black holes into Schwarzschild spacetime has enabled the simultaneous existence of event and acoustic horizons, as derived from the Gross-Pitaevskii theory. This paper investigates the dynamics of a particle-like vortex in free fall as it approaches the horizon of a curved slowly-rotating acoustic black hole, specifically within the context of the Lens-Thirring spacetime. We analyze the circular orbits of vortices around the acoustic black hole and delve into the chaotic motion of the vortex at the unstable equilibrium in the vicinity of the horizon. Furthermore, we explore whether a universal bound exists for the Lyapunov exponent characterising this chaotic motion, drawing parallels to the known bounds for the particle motion in general relativity. We anticipate that future experiments will be able to corroborate these findings.