Quantum fluxes and Φ2 for a non-minimally coupled scalar field: ringdown and tail on approaching the polar Kerr inner horizon

Abstract

We compute Φ2ren as well as the energy fluxes Tuuren and Tvvren (where u and v are the standard Eddington-Finkelstein coordinates) associated with a quantum massless real scalar field Φ, with a general curvature coupling constant ξ, near the inner horizon (IH) of a Kerr black hole, along the axis of rotation. The quantum field is in the Unruh state, corresponding to an evaporating black hole. We renormalize these quantities by the state-subtraction method. We drop the assumption of minimal coupling to the curvature, thereby generalizing the results of arXiv:2203.08502 for the fluxes at the IH. This requires understanding the asymptotic behavior of Φ2ren neat the IH. State subtraction allows us to push the computation of Φ2ren along the axis of rotation in the Kerr interior in arXiv:2409.17464 deeper into the near-IH region, exposing their final asymptotic behavior on approaching the IH. For Φ2ren (a ξ-independent quantity in the Kerr case), we find that the approach to its finite asymptotic IH value is given, per -mode, by a ringdown phase (namely exponentially damped oscillations), followed by an inverse-power tail, both in the tortoise coordinate r* (which diverges at the IH). Interestingly, in the regime where the ringing dominates, the ringing's complex frequencies are (numerically) found to match twice the well-known classical quasinormal-mode frequencies in Kerr, and the inverse-power tails are found to be r*-2-3 (resembling Price's law in the classical black hole exterior, upon replacement t r*). [Abridged]