Novel black-hole solutions in Einstein-scalar-Gauss-Bonnet theories with a cosmological constant

Bakopoulos, Athanasios; Antoniou, Georgios; Kanti, Panagiota

doi:10.1103/physrevd.99.064003

Cited by 95 publications

(87 citation statements)

References 137 publications

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“…for all forms of the coupling function f (φ), with D being the scalar charge, as found in [39]. For Λ < 0 and V (φ) = 1, black-hole solutions with an asymptotically Anti-de Sitter behaviour are expected to emerge as in [60,160]. These solutions do not possess a scalar charge since the asymptotic behaviour of the scalar field is given by the expression…”

Section: Asymptotic Solutionsmentioning

confidence: 96%

“…To this end, we assume that, as r → r h , the metric function e A(r) should vanish (and e B(r) should diverge) whereas the scalar field must remain finite. As was explicitly shown in previous constructions [39,160], this amounts to working in the limit A (r) → ∞ while keeping φ (r) and φ (r) finite as the black-hole horizon is approached. Working in these limits, Eq.…”

Section: Asymptotic Solutionsmentioning

confidence: 99%

“…For V (φ) = 1, the expression of C may take the form of a second-order polynomial foṙ f 2 h , which then leads to two branches of black-hole solutions (or four, if negative values oḟ f h are also allowed) describing solutions having either a minimum or a maximum horizon radius [60,160]. In reality, only solutions with a minimum horizon radius are found while the second branch is plagued by instabilities.…”

Section: Asymptotic Solutionsmentioning

confidence: 99%

“…where F = I E /β is the Helmholtz free-energy of the system given in terms of the Euclidean version of the action I E , and β = 1/(k B T ). However, as was discussed in [160,177,178], this formula needs to be appropriately modified when the spacetime asymptotic solution deviates from the asymptotically-flat limit. Equivalently, as was demonstrated in [178], one may employ an alternative method developed in [179,180] in which the entropy of the black hole is identified with the Noether charge on the horizon under diffeomorphisms.…”

Section: Thermodynamical Analysismentioning

confidence: 99%

“…In a previous work [160], we studied the EsGB theory in the presence of a negative cosmological constant Λ, and demonstrated that black-hole solutions with an asymptotically Anti-de Sitter behaviour and a scalar hair arise as easily as their asymptotically-flat counterparts. In the present work, we will address the case where this constant energy density is replaced by a non-trivial potential for the scalar field.…”

Section: Introductionmentioning

confidence: 98%

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Large and ultracompact Gauss-Bonnet black holes with a self-interacting scalar field

2020

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We consider the Einstein-scalar-Gauss-Bonnet theory, and study the case where a negative cosmological constant is replaced by a more realistic, negative scalar-field potential. We study different forms of the coupling function between the scalar field and the Gauss-Bonnet term as well as of the scalar potential. In all cases, we obtain asymptotically-flat, regular black-hole solutions with a non-trivial scalar field which naturally dies out at large distances. For a quadratic negative potential, two distinct subgroups of solutions emerge: the first comprises light black holes with a large horizon radius, and the second includes massive, ultra-compact black holes. The most ultra-compact solutions, having approximately the 1/20 of the horizon radius of the Schwarzschild solution with the same mass, emerge for the exponential and linear coupling functions. For other polynomial forms of the scalar potential, the subgroup of ultra-compact solutions disappears, and the black holes obtained may have a horizon radius larger or smaller than the Schwarzschild solution depending on the particular value of their mass.

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Section: Asymptotic Solutionsmentioning

confidence: 96%

Section: Asymptotic Solutionsmentioning

confidence: 99%

Section: Asymptotic Solutionsmentioning

confidence: 99%

Section: Thermodynamical Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

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Large and ultracompact Gauss-Bonnet black holes with a self-interacting scalar field

2020

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Analytic and asymptotically flat hairy (ultra-compact) black-hole solutions and their axial perturbations

Bakopoulos

Nakas

2022

J. High Energ. Phys.

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In this work, we consider a very simple gravitational theory that contains a scalar field with its kinetic and potential terms minimally coupled to gravity, while the scalar field is assumed to have a coulombic form. In the context of this theory, we study an analytic, asymptotically flat, and regular (ultra-compact) black-hole solutions with non-trivial scalar hair of secondary type. At first, we examine the properties of the static and spherically symmetric black-hole solution — firstly appeared in [109] — and we find that in the causal region of the spacetime the stress-energy tensor, needed to support our solution, satisfies the strong energy conditions. Then, by using the slow-rotating approximation, we generalize the static solution into a slowly rotating one, and we determine explicitly its angular velocity ω(r). We also find that the angular velocity of our ultra-compact solution is always larger compared to the angular velocity of the corresponding equally massive slow-rotating Schwarzschild black hole. In addition, we investigate the axial perturbations of the derived solutions by determining the Schrödinger-like equation and the effective potential. We show that there is a region in the parameter space of the free parameters of our theory, which allows for the existence of stable ultra-compact black hole solutions. Specifically, we calculate that the most compact and stable black hole solution is 0.551 times smaller than the Schwarzschild one, while it rotates 2.491 times faster compared to the slow-rotating Schwarzschild black hole. Finally, we present without going into details the generalization of the derived asymptotically flat solutions to asymptotically (A)dS solutions.

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Compact objects of spherical symmetry in beyond Horndeski theories

Bakopoulos

Charmousis

Kanti

et al. 2022

J. High Energ. Phys.

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We analyse in all generality beyond Horndeski theories of shift symmetry in a static and spherically symmetric spacetime. By introducing four auxiliary functions, we write the field equations in a particularly compact form. We show that assuming additionally parity symmetry renders the system directly integrable giving multiple families of black-hole solutions. These have typically an asymptotically-flat Reissner-Nordstrom behaviour, and emerge in the presence of a canonical kinetic term for the scalar field. In the absence of parity symmetry, we present a general method which allows us to integrate the field equations by choosing the form of only one coupling function and an auxiliary quantity. This method leads to asymptotically flat and AdS black hole solutions with differing properties. We finally discuss disformal transformations within this context as a means of obtaining wormhole and black hole solutions in different theories.

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Novel black-hole solutions in Einstein-scalar-Gauss-Bonnet theories with a cosmological constant

Cited by 95 publications

References 137 publications

Large and ultracompact Gauss-Bonnet black holes with a self-interacting scalar field

Large and ultracompact Gauss-Bonnet black holes with a self-interacting scalar field

Analytic and asymptotically flat hairy (ultra-compact) black-hole solutions and their axial perturbations

Compact objects of spherical symmetry in beyond Horndeski theories

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