Tidal dynamics and stellar disruption in charged Kalb-Ramond black holes in nonlinear electrodynamics

Abstract

We investigate tidal forces, geodesic deviation, and tidal disruption in the black hole spacetime described by the Kalb-Ramond-ModMax solution, where electromagnetic nonlinearity is governed by the parameter γ and Lorentz symmetry violation by the parameter l. In the canonical sector (α=1), the radial tidal force exhibits a transition marked by a sign inversion between the horizons r- and r+, signaling internal regimes of radial compression analogous to those of charged black holes; the parameter l controls the strength and location of this transition, while γ regulates the nonlinear electromagnetic contribution. The angular tidal force is predominantly compressive, l shaping the effective geometry, and γ acting as a damping factor. In the phantom sector (α=-1), tidal forces and geodesic deviation diverge, indicating a tidal instability, with l and γ affecting only the magnitude of the response. We further show that l shifts the relation between the horizon radius r+ and the tidal disruption radius r Roche, thereby modifying the critical (Hills) mass defined by r Roche=r+. Tidal disruption of neutron stars occurs inside the horizon for supermassive black holes, whereas Sun-like stars are disrupted outside the horizon, with γ becoming relevant only for ultramassive black holes with masses 108M. Our results demonstrate that Kalb-Ramon-ModMax effects are largely suppressed for supermassive black holes, but may be relevant for intermediate-mass systems and observable tidal disruption events, offering an indirect probe of Lorentz violation and nonlinear electrodynamics in the strong-field regime.