Holographic CFT phase transitions and criticality for charged Gauss–Bonnet AdS black holes in the ensemble at fixed

Limin Zeng

doi:10.1140/epjc/s10052-025-15184-9

2024 Impact factor 4.8

Particles and Fields

Open Access

Eur. Phys. J. C (2025) 85: 1440
https://doi.org/10.1140/epjc/s10052-025-15184-9

Regular Article - Theoretical Physics

Holographic CFT phase transitions and criticality for charged Gauss–Bonnet AdS black holes in the ensemble at fixed $(C, V, \tilde{Q}, \tilde{A})$ $Mathematical equation: $$(C, \mathcal {V}, \tilde{Q}, \tilde{\mathcal {A}})$$$

Limin Zeng¹^,2^,3^a

¹ School of Fundamental Physics and Mathematical Sciences, Hangzhou Institute for Advanced Study, UCAS, 310024, Hangzhou, China
² Institute of Theoretical Physics, Chinese Academy of Sciences, 100190, Beijing, China
³ University of Chinese Academy of Sciences, 100049, Beijing, China

^a This email address is being protected from spambots. You need JavaScript enabled to view it.

Received: 10 October 2025
Accepted: 6 December 2025
Published online: 18 December 2025

Abstract

We study the holographic dual of the extended thermodynamics of spherically symmetric, charged Gauss–Bonnet AdS black holes in the context of the AdS/CFT correspondence. Compared to Einstein’s theory of gravity, Gauss–Bonnet gravity introduces higher-order curvature terms. The coupling constants of these higher-order curvature terms $α$ $Mathematical equation: $$\alpha $$$ can serve as new thermodynamic quantities, which will also be dual to thermodynamic quantities on the boundary CFT, a feature not present in the CFT dual to Einstein’s gravity previously. Based on the holographic dictionary, we studied the critical behavior and phase transition of the CFT description of the charged Gauss–Bonnet black holes in $d = 4$ Mathematical equation: $$d=4$$ and $d = 5$ Mathematical equation: $$d=5$$ in the ensemble at fixed $(C, V, \tilde{Q}, \tilde{A})$ $Mathematical equation: $$(C, \mathcal {V}, \tilde{Q}, \tilde{\mathcal {A}})$$$ . The interesting behaviour of free energy stems from the fact that the constraints we introduced to handle the gravitational constant on CFT and the AdS radius differ from conventional approaches. Using the criticality equation, we numerically found the critical points of the zeroth-order and first-order phase transition for $\tilde{A}$ $Mathematical equation: $$\tilde{\mathcal {A}}$$$ . The relationships between conjugate thermodynamic pairs (equation of state) were also examined. In the case of the $p - V$ $Mathematical equation: $$p-\mathcal {V}$$$ , $\tilde{T} - \tilde{S}$ $Mathematical equation: $$\tilde{T}-\tilde{S}$$$ and $\tilde{Φ} - \tilde{Q}$ $Mathematical equation: $$\tilde{\varPhi }-\tilde{Q}$$$ conjugate pairs, characteristics that are analogous to the first-order phase transition of van der Waals fluids were found.

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Holographic CFT phase transitions and criticality for charged Gauss–Bonnet AdS black holes in the ensemble at fixed (C,V,Q~,A~)

Conference announcements

Holographic CFT phase transitions and criticality for charged Gauss–Bonnet AdS black holes in the ensemble at fixed $(C, V, \tilde{Q}, \tilde{A})$ $Mathematical equation: $$(C, \mathcal {V}, \tilde{Q}, \tilde{\mathcal {A}})$$$