Double-trace instability of BTZ black holes

Abstract: We perform a comprehensive study of the linear stability of rotating BTZ black holes under massive scalar field perturbations with double-trace boundary conditions. While BTZ black holes are stable under standard Dirichlet and Neumann boundary conditions, we demonstrate that they can develop instabilities when subjected to double-trace boundary conditions. Our key findings are threefold. First, we show that BTZ black holes exhibit instabilities not only for non-axisymmetric modes $\unicode{x2013}$ previously the only known unstable sector $\unicode{x2013}$ but crucially also for axisymmetric modes. Second, we prove that the axisymmetric instability is the dominant and most fundamental: configurations unstable to any non-axisymmetric mode are already unstable to the axisymmetric one. Third, we identify regions in the BTZ parameter space where these black holes are unstable while global AdS$_3$ remains stable, and we map the complete onset curves that determine the corresponding stability boundaries. Unlike conventional superradiant instabilities, the BTZ double-trace instability occurs for angular velocities always satisfying the Hawking-Reall bound. We trace the physical origin of these instabilities to the influx of energy and angular momentum through the asymptotic boundary permitted by double-trace deformations for a particular sign of the coupling, rather than to near-horizon effects. Our results provide a prototype for understanding double-trace instabilities in higher-dimensional rotating AdS black holes and suggest the existence of rotating hairy black hole solutions with scalar condensates, which we construct in a companion paper.