Gauss-Bonnet corrected string/black hole transition in large dimensions

TL;DR

This paper analytically studies the string/black hole transition in large dimensions, incorporating Gauss-Bonnet corrections, and derives explicit corrections to the transition point and related thermodynamic properties.

Contribution

It provides a unified analytic framework including higher-derivative corrections for the string/black hole transition in large dimensions, with explicit solutions and matching procedures.

Findings

Derived the orrected decay exponent and Hagedorn temperature shift.

Constructed closed-form Euclidean solutions in Einstein-Gauss-Bonnet theory.

Matched near-zone and far-zone solutions to determine corrected saddle points.

Abstract

We develop a unified analytic treatment of the Horowitz--Polchinski string/black hole correspondence that systematically incorporates higher-derivative corrections to gravity. Working in Euclidean signature -- where the Euclidean black hole and the thermal scalar arise as competing saddles of the same finite-temperature ensemble -- we include the Gauss--Bonnet term. The analysis is rendered tractable in this UV--sensitive regime by the large-\(D\) expansion, which sharply separates the geometry into a universal near-zone and an asymptotic far-zone. In the near-zone, the coupled large-\(D\) equations reduce the thermal-scalar sector to an exactly solvable Schr\"odinger problem, from which we extract the \(\alpha'\)-corrected decay exponent and the corresponding shift of the Hagedorn temperature. In the far-zone, we construct closed-form Euclidean solutions of Einstein--Gauss--Bonnet theory at leading order in both \(1/D\) and \(\alpha'\). Matching the two regions yields the complete corrected saddle -- fixing its temperature, horizon data, and on--shell action -- and permits a fully analytic comparison of free energies between the thermal-scalar and black hole phases. This provides a controlled derivation of the HP correspondence point with explicit higher-curvature corrections.