Instability of regular planar black holes in four dimensions arising from an infinite sum of curvature corrections

Abstract

In four-dimensional scalar-tensor theories derived via dimensional regularization with a conformal rescaling of the metric, we study the stability of planar black holes (BHs) whose horizons are described by two-dimensional compact Einstein spaces with vanishing curvature. By taking an infinite sum of Lovelock curvature invariants, it is possible to construct BH solutions whose metric components remain nonsingular at r=0, with a scalar-field derivative given by φ'(r)=1/r, where r is the radial coordinate. We show that such BH solutions suffer from a strong coupling problem, where the kinetic term of the even-parity scalar-field perturbation associated with the timelike coordinate vanishes everywhere. Moreover, we find that these BHs are subject to both ghost and Laplacian instabilities for odd-parity perturbations near r=0. Consequently, the presence of these pathological features rules out regular planar BHs with the scalar-field profile φ'(r)=1/r as physically viable and stable configurations.