Background subtraction for black hole thermodynamics is valid and equivalent to Iyer-Wald in matter-coupled gravity theories, with smooth performance in examples but subtleties for certain matter fields.
Holography of Charged Black Holes with $RF^2$ Corrections
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abstract
We investigate several holographic properties of charged black holes with $RF^{2}$ corrections, which originate from Kaluza-Klein reductions of five-dimensional Gauss-Bonnet gravity. We obtain the perturbative solution and discuss its thermodynamics. The DC conductivity is calculated via the effective action approach and the corrections to the DC conductivity are also evaluated. Moreover, we calculate the shear viscosity $\eta$ and thermal conductivity $\kappa_{T}$, as well as two interesting ratios $\eta/s$ and $\kappa_{T}\mu^{2}/(\eta T)$. We find that both bounds conjectured in the literatures can be violated in the presence of the higher order corrections $RF^2$.
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gr-qc 1years
2025 1verdicts
UNVERDICTED 1representative citing papers
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Validity of the Background Subtraction Method for Black Hole Thermodynamics in Matter-Coupled Gravity Theories
Background subtraction for black hole thermodynamics is valid and equivalent to Iyer-Wald in matter-coupled gravity theories, with smooth performance in examples but subtleties for certain matter fields.