Thermodynamics of Hairy Black Holes in Quantum Regimes: Insights from Horndeski Theory

Abstract

We study non-perturbative quantum gravitational corrections to the thermodynamics and quantum work distribution of the n-dimensional Schwarzschild--Tangherlini--Anti-de Sitter black hole. Starting from the corrected entropy S = S0 + η\, e-S0, where S0 is the Bekenstein--Hawking entropy, we derive the modified specific heat, internal energy, Helmholtz free energy, and Gibbs free energy in closed form. The specific heat retains the classical divergence at rh*=l(n-3)/(n-1) for n≥ 4, but the quantum correction suppresses its magnitude by up to 78\% at small horizon radii. In the extended phase space, the uncharged black hole admits no van der Waals critical point; however, the non-perturbative correction induces a Hawking--Page transition for n≥ 4 that is absent in the semi-classical limit. The corrected Gibbs free energy turns negative at small rh, opening a thermodynamic channel with no classical counterpart. Using the Jarzynski equality and Jensen inequality, we obtain the quantum work distribution during evaporation. The free energy difference F between two black hole states undergoes a sign reversal at small horizon radii for n≥ 4 when η=1, flipping the average quantum work from negative to positive. This sign reversal grows with the spacetime dimension, reaching W ≈ +4.31 for n=10. These findings demonstrate that non-perturbative quantum gravitational effects qualitatively alter the phase structure and evaporation energetics of AdS black holes, and they cannot be captured by perturbative corrections alone.

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