Cauchy-horizon flux coefficients in the reduced Polyakov model

Abstract

We derive the leading Cauchy-horizon flux coefficient in the stationary reduced Polyakov sector of spherically symmetric charged black holes. For a nonextremal inner horizon with affine coordinate \(V-=-e-κ-v\), a finite late-time Eddington--Finkelstein flux \(F-(∞)=v+∞ Tvv\) is amplified as \( TV-V- F-(∞)/(κ-2V-2)\). In the stationary reduced Polyakov model, \(F-(∞)=tv-Nκ-2/(48π)\). Thus the leading pure \(V--2\) Polyakov coefficient is absent precisely on the inner-horizon cancellation surface \(tv=Nκ-2/(48π)\). The future event horizon determines the distinct outgoing condition \(tu=Nκ+2/(48π)\), so the two horizons select different loci in the stationary \((tu,tv)\) state space. Standard outer prescriptions, such as the asymptotically flat Unruh prescription and the outer-horizon thermal/KMS prescription, generically lie away from the inner-horizon cancellation surface and generate nonzero inner-horizon coefficients. We then analyze the total flux hierarchy \(Tvv tot=F0+Av-p+o(v-p)\): cancellation of the pure quadratic coefficient is the constant-level condition \(F0=0\), while nonzero Price-tail terms give logarithmically weakened divergences. This state-space formulation gives an exact characterization of Cauchy-horizon flux amplification in the anomaly-induced radial sector and shows that, when the total coefficient is nonzero, the corresponding radial null curvature diverges.