A Cardy-like formula for rotating black holes with planar horizon

We show that the semiclassical entropy of $D$-dimensional rotating (an)isotropic black holes with planar horizon can be successfully computed according to a Cardy-like formula. This formula does not refer to any central charges but instead involves the vacuum energy which is identified with a gravitational bulk soliton. The soliton is obtained from the non-rotating black hole solution by means of a double analytic continuation. The robustness of the Cardy-like formula is tested with numerous and varied examples, including AdS, Lifshitz and hyperscaling violation planar black holes.


Introduction
Since the seminal works of Bekenstein and Hawking [1,2], black holes are believed to behave as thermodynamic objects with characteristic temperature and entropy. A natural question has then emerged concerning the statistical interpretation of the black hole entropy. One of the first results that has shed some light on this problem was the observation that the asymptotic symmetries of the three-dimensional AdS space consist in two copies of the Virasoro algebra with a central charge [3]. This latter corresponds to the symmetry group of a two-dimensional CFT and, in this case, the Cardy formula is well-appropriate to express the asymptotic density of states [4]. An important manifestation of the AdS/CFT correspondence was then provided by showing that the Cardy formula applied for the BTZ black hole [5] correctly reproduces the expression of the Bekenstein-Hawking entropy [6]. Soon after, this approach was generalized for higher-dimensional black holes having a two-dimensional CFT dual in the case of standard General Relativity [7] as well as in presence of higher-derivative corrections [8].
Extensions of the Cardy formula have been considered and studied in the current literature. Among other, one can mention the higher-dimensional generalization of the Cardy formula which applied for strongly coupled field theories having an AdS dual [9]. There also exist extensions of the Cardy formula with applications for three-dimensional spacetimes that are not AdS like the warped AdS spaces [10] or anisotropic spacetimes, namely the Lifshitz spacetimes [11] or the hyperscaling violation geometries [12,13]. The interest on anisotropic spacetimes has considerably grown up this last decade essentially due to the will of extending the ideas underlying the gauge/gravity duality to strongly coupled field theories with an anisotropic scaling symmetry [14]. Notice also that the cases of three-dimensional black holes have permitted a better comprehension of the holographic derivation of the entropy by highlighting the prominent role played by the soliton, see Refs. [15,16,17]. This observation is not in contradiction with the standard derivation of the Cardy formula for which the ground state is implicitly assumed to be the three-dimensional AdS spacetime. Nevertheless, this assumption is in general valid only for the vacuum sector but not in the hairy sector which possesses a different ground state. It is then more judicious to deal with a Cardy formula written in terms of the vacuum energy rather than the central charges. Unfortunately, it is not possible a priori to find out the vacuum energy of the putative field theory. However, as stressed in Refs. [15,16,17], the vacuum energy can be identified with the mass of a bulk soliton constructed from the black hole through a double Wick rotation in the same way that the AdS soliton [18], which reinforces the importance of the role played by the soliton. Importance also confirmed in the Lifshitz case [11] where the robustness of the Lifshitz Cardy formula has been tested successfully for three-dimensional Lifshitz black holes with a nonminimally scalar field [19].
One of the aim of this paper is precisely to confirm the importance of the gravitational soliton. We will highlight this importance in the case of rotating black holes in arbitrary dimension D with a planar base manifold. This restriction on the horizon's topology is justified by the fact that the soliton can be easily constructed from the black hole by a double analytic continuation similar to the one operated in the AdS soliton [18]. With the view of achieving this task, we will be interested on higher-dimensional extensions of the Cardy formula for field theories satisfying the following two assumptions: (i) the field theory possibly displays a hyperscaling violation reflected by the fact that the thermal entropy S scales with respect to the temperature as S ∼ T validity of the Cardy-like formula considering gravity theories whose spectrum of solutions contain black holes whose entropy exhibits a power law temperature as described in the hypothesis (i) as well as regular solitons (ii). This inspection will be done for different classes of black hole solutions with different asymptotic behaviors (rotating AdS, Lifshitz and hyperscaling violation black holes with a planar base manifold) by comparing the gravitational entropy with the entropy field expression involving the effective spatial dimension and the vacuum energy. In all our examples, the spinning planar black holes are derived from static configurations through a Lorentz boost and the vacuum energy corresponds to the mass of the gravitational soliton obtained from the nonrotating black hole through a double Wick rotation. We will also extend these results to the case of charged planar black holes, where again the ground state is identified with the soliton derived from the neutral and nonrotating black hole. Since the soliton is devoid of any integration constant, its mass will be computed using the quasilocal generalization of the ADT formalism [21] as presented in Refs. [22,23]. One of the main result of these two last papers lies in the prescription of the off-shell ADT potential Q µν ADT in terms of the off-shell Noether potential K µν and the surface term Θ µ arising from the variation of the action where ξ µ denotes the Killing vector. The corresponding conserved charge is computed to be where ∆K µν (ξ) ≡ K µν s=1 (ξ) − K µν s=0 (ξ) denotes the difference of the Noether potential between the black hole and the zero-mass solution, and d D−2 x µν represents the integration over the codimension two boundary. For the examples treated in this paper, the action can schematically be written as where φ is a scalar field (possibly a dilatonic field) with its usual kinetic term and A (i) = A (i)µ dx µ stand for Abelian gauge fields or Proca fields. In this generic case, the boundary term and Noether potential needed to compute the charge (1.2) are given by where P µνρσ = ∂L ∂Rµνρσ , and R µνρσ is the Riemann tensor. The plan of the paper is organized as follows. In the next section, a general formula for the asymptotic growth of the number of states including the angular momentum is proposed. This generic Cardy-like formula involves the effective spatial dimension d eff , the Lifshitz dynamical exponent z, the mass and angular momentum of the black hole as well as the vacuum energy which corresponds to the mass of the bulk soliton. In Sec. 3, we corroborate the validity of the Cardy-like formula in the isotropic case z = 1 with stationary cylindrical black holes. The case of a three-dimensional black hole solution of the Einstein equations with a source given by a self-interacting scalar field with a super-renormalizable potential is also treated in full details. Lovelock AdS black holes will also be inspected in order to reinforce the validity of the Cardy-like formula. To end the Sec. 3, two examples of hyperscaling violating black holes with different effective spatial dimensionality will be studied. In Sec. 4, we will deal with the anisotropic case z = 1. Lifshitz black holes solutions of higher-order gravity theories will be our first testing example while the case of charged anisotropic black holes produced by various dilaton fields will constitute our second class of example. Finally, the last section is devoted to the summary and to the concluding remarks. For simplicity, we have decided to fix the radius of curvature to unit, l = 1, while the Newton gravitational constant G is defined through the change 2κ = 16πG.

General formula for the asymptotic growth of the number of states
As recalled in the introduction, the asymptotic symmetries of AdS 3 are represented by two copies of the Virasoro algebra with equal left and right moving central charges (in our convention l = 1 and 2κ = 16πG), and the standard Cardy formula takes the following form where ∆ ± = 1 2 (M ± J) are the eigenvalues of the left and right Virasoro operators. In this representation of the Cardy formula, it is implicitly assumed that the ground state is identified with the AdS spacetime. Nevertheless, the AdS spacetime is only a suitable ground state in the case of standard General Relativity, and this assumption is not longer valid in presence of source for example. Hence, it is more reasonable to deal with a Cardy formula involving the vacuum charge than the central charge. In the vacuum sector for standard General Relativity, the ground state is nothing but the three-dimensional AdS soliton whose mass is computed below (3.9) and gives M sol = −π/κ. Finally, the standard Cardy formula (2.1) can be as well expressed as Notice that Cardy-like formulas involving the vacuum energy instead of the central charges have been proved to be very useful for examples where the ground state is not the three-dimensional AdS spacetime, see e. g. [11,12,13,15,16,17]. The matching between the gravitational entropy and the Cardy formula (2.2) is perfectly consolidated for three-dimensional black holes that are asymptotically AdS (even in the weaker sense). Nevertheless, as mentioned in the introduction, we are interested on generalizations of the Cardy formula that apply for field theories displaying an hyperscaling violation behavior such that the thermal entropy S scales w. r. t. the temperature T as where d eff is an effective spatial dimensionality and z is the Lifshitz exponent. In order to achieve this task, we closely follow the derivations done in Refs. [12,20]. The partition function Z defined on the torus of modulus τ such that 2πτ = 2πr e iφ and 2πτ = 2πr e −iφ can be written as In the microcanonical ensemble, the entropy is basically the logarithm of the density of states S ∼ log ρ(M, J). Defining the quantity and assuming that Z 0 presents the following modular invariance the density of states ρ(M, J) can be re-written as Now, as usual, this last expression can be evaluated using a saddle-point approximations for r and φ, and assuming that Z 0 varies slowly, one gets . (

2.4)
This formula constitutes the extension of the Cardy formula (2.2) in arbitrary dimension for a field theory with a spatial effective dimension d eff and dynamical exponent z.
Let us see the consistency of this expression with known formulas. First of all, in the isotropic case z = 1, the expression (2.4) is compatible with the Cardy formula (2.2) in the standard AdS case in three dimensions (which corresponds to d eff = 1) as well as with the formula derived in [20] for hyperscaling violation metric. On the other hand, in the nonrotating case with anisotropy, i. e. J = 0 with z = 1, the formula (2.4) reproduces the Lifshitz Cardy formula in three dimensions with d eff = 1, see [11], and also the generic formula for hyperscaling violation metric [12,13].
In the electrically charged case, the Cardy-like formula (2.4) becomes where φ e denotes the electric potential while Q e stands for the electric charge.

Corroborating the Cardy-like formula in the isotropic case, z = 1
In this section, we will be mainly concerned with planar black holes that are asymptotically AdS or exhibiting an hyperscaling violation behavior. In these cases, the asymptotic form of the metric can be parameterized as follows where θ represents the parameter responsible of the violation of the hyperscaling property, and θ = 0 will correspond to the planar AdS case. Note that, for the asymptotic metric (3.1), the isotropic transformations t → λt, r → λ −1 r and x i → λx i are identified as an isometry in the AdS case, and as a conformal transformation for non vanishing θ. For this class of black holes, the dynamical exponent appearing in the Cardy-like formula (2.4) corresponds to the isotropic situation z = 1 while the effective spatial dimension d eff is given by d eff = D − 2 in the AdS case (θ = 0) otherwise it will depend explicitly on the violating parameter θ. In the hyperscaling case, one of the difficulty is to correctly identify the functional dependence of the effective spatial dimension. For example, for Einstein gravity with scalar field source, the effective spatial dimension is d eff = D−2−θ, while for higher-order gravity theories, this dependence may be different as shown below, see also [13].
In what follows, we will treat various isotropic examples with the aim of testing the Cardy-like formula, starting from AdS planar black holes. As a first example, we examine D−dimensional stationary cylindrical black holes solutions of Einstein gravity with a negative cosmological constant. We also look at the case of a three-dimensional solution of Einstein gravity with a self-interacting scalar field with a super-renormalizable potential. The case of higher theories is also inspected through the analysis of Lovelock AdS black holes. In the second part, two examples of hyperscaling violation black holes will be studied. The first testing example is described by the Einstein gravity with a scalar field source corresponding to a spatial dimensionality d eff = D − 2 − θ. Next, in order to test the force of the Cardy-like formula with a different spatial dimensionality, we deal with an hyperscaling violating black hole solution of a pure quadratic gravity theory.

Stationary cylindrical black holes
We start the corroborating study of the Cardy-like formula (2.4) with the case of the Einstein field equations in the presence of a negative cosmological constant and whose corresponding action is We consider the higher-dimensional extension of the stationary cylindrical black hole found by Lemos [24] in four dimensions and reported in [25], Here n = [(D − 1)/2] corresponds to the number of rotation parameters a i , Ξ = 1 + n i a 2 i , and the metric function reads In four dimensions, the number of rotations is n = 1, and the solution reduces to the stationary cylindrical black hole solution of Lemos [24]. As calculated in Ref. [25], the entropy of the solution is with mass and angular momenta given by where Vol(Σ D−2 ) corresponds to the volume element of the (D − 2)-dimensional Euclidean space.
In order to test the validity of the Cardy-like formula (2.4), one needs to construct the static soliton and to compute its mass through the quasilocal expression (1.2). As explained in the introduction, operating a double Wick rotation on the static version of the solution, that is Eq. (3.3) with a i = 0, one gets the AdS soliton [18] (3.7) The next step is to determine the mass of the soliton through the quasilocal formula (1.2) where the Killing vector field is ξ t = ∂ t . The variation of the Noether potential and the surface term are given by (3.8) Finally, the mass of the D−dimensional AdS gravitational soliton reads and it is simple to check that the formula (2.4) where J 2 is now understood as J 2 = n i=1 J 2 i and where d eff = D − 2 and z = 1 correctly reproduces the gravitational entropy (3.4).

Black hole with a super-renormalizable self-interacting scalar field in 3D
We pursue our survey considering now a three-dimensional toy model whose action is described by the Einstein-Hilbert piece with a cosmological constant together with a nonminimally selfinteracting scalar field The nonminimal coupling corresponds to the conformal one in three dimensions, and as it is well known the potential term which is compatible with the conformal invariance of the matter source is U (φ) ∝ φ 6 . Nevertheless, in our case, we chose a potential term breaking the conformal invariance of the matter action, and defined by all the powers lower than the conformal one (super-renormalizable potential), that is The field equations obtained from the variation of the action (3.10) with respect to the metric and the scalar field are In Ref. [27], the authors have derived a static black hole solution of the model described by (3.10-3.11-3.12) using a conformal machinery where the coupling constants are parameterized as follows More precisely, as shown in [27], the action defined by (3.10-3.11-3.13) can be obtained from the conformally invariant action 1 denoted byS[g,φ] and corresponding to the action (3.10) with the potential U ∝φ 6 through a map parameterized by the factor λ, and both actions are related as follows (3.14) In fact, the static solution reported in [27] was constructed using the one-parameter mapping with a seed configuration given by the solution of the conformally self-interacting version of the Martinez-Zanelli solution [28] found in [29]. Instead of writing down the static solution [27], we report its spinning extension obtained from the static configuration as usual in three dimensions through a Lorentz boost defined by and well-defined for ω 2 < 1. The line element of the resulting rotating solution is given by where the metric functions and the scalar field read We now analyze the thermodynamical properties of the spinning solution through the Euclidean method where the Euclidean time τ is imaginary τ = it and periodic of period β which is the inverse of the temperature β = T −1 . The Euclidean action I Euc is related with the free energy F by where M is the mass, S the entropy and Ω is the chemical potential corresponding to the angular momentum J. On the other hand, in order to display the boundary term B that will ensure the finiteness of the Euclidean action, we find more convenient to consider the following class of Euclidean metric with the assumption that the scalar field only depends on the radial coordinate, φ = φ(r).
where 20) and the Hamiltonian H is given by .
In the reduced action (3.19), B is a boundary term that is fixed by requiring that the Euclidean action has an extremum, that is δI E = 0 ; this last condition in turn implies that where the variation is taken between the horizon and the infinity. The temperature is fixed requiring regularity of the metric at the horizon yielding to and for the solution (3.17), one obtains We do not display the field equations of the reduced action (3.19) but their full integration will reproduce the solution (3.17) with We are now in position to compute the boundary term. Its contribution at the infinity gives while at the horizon, one gets Finally, the boundary term is given by and hence the comparison between (3.23) and (3.18) permits the identification of the entropy as well as the mass, angular momentum and angular velocity that are given by It is interesting to note that the values of the entropy, the mass and the angular momentum of the black hole solution with the super-renormalizable potential are precisely (1 − λ 2 ) time those of the black hole solution with the conformal potential [28,29]. This is not surprising and can be explained as follows. On one hand, the actions being proportional with that precise factor (3.14), so that their Euclidean actions On the other hand, since the temperatures and the chemical potentials are the same for both solution, T =T and Ω =Ω, we have by virtue of (3.18) For completeness, we also notice that the first law of thermodynamics is satisfied Once again, in order to display the role played by the gravitational soliton for computing the entropy, we construct the gravitational soliton and derive its mass. The soliton obtained from the static black hole configuration, Eqs (3.16-3.17) with ω = 0, through a double Wick rotation reads For a Killing vector ξ t = (1, 0, 0), the surface term and the variation of the Noether potential read yielding to a mass of the soliton (1.2) given by Finally, it is easy to check that the formula of the gravitational entropy (3.24) is correctly reproduced by means of the Cardy-like formula (2.4) using the conserved quantities (3.25) and the mass of the gravitational soliton (3.28).

Lovelock AdS black holes
In General Relativity, two of the main fundamental assumptions are the requirement of general covariance and the fact that the field equations for the metric are at most of second order. In three and four dimensions, these requirements automatically single out the gravity theory to be described by the Einstein-Hilbert action plus eventually a cosmological constant. However, for dimensions greater than four, a more general gravity theory, the so-called Lovelock theory, satisfies these standard requirements [30]. The D−dimensional Lovelock Lagrangian is a D−form constructed out of the vielbein, the spin connection and their exterior derivative and is given by where R ab = d ω ab + ω a c ω cb is the curvature two-form, the coefficients α p are arbitrary dimensionful coupling constants and the wedge product between differential forms is understood. We recognize the first two terms of the Lovelock Lagrangian to be proportional to the cosmological constant and to the Einstein-Hilbert piece. Being D−dimensional forms, the Lovelock actions are automatically invariant under the local Lorentz transformations. In addition, in odd dimension, this Lorentz gauge symmetry can be enlarged for a particular choice of the coefficients α p to a local (A)dS or Poincaré symmetry group ; the resulting Lagrangians are called Chern-Simons, see e. g. [31] for a review on Chern-Simons theory. As shown in [32], the coefficients α p can also be chosen such that the theory has a unique AdS vacuum with a fixed value of the cosmological constant. In doing so, one yields to a series of inequivalent actions indexed by an integer n with 1 ≤ n ≤ [(D − 1)/2], and given by (3.29) or in tensorial form by where L GB = R 2 − 4R αβ R αβ + R µναβ R µναβ stands for the Gauss-Bonnet Lagrangian and L (3) is given by Using differential forms, the field equations arising from the variation of the action (3.29) with respect to the vielbein and the spin connection read ǫ aa 2 ···a DR a 2 a 3 · · ·R a 2n−1 a 2n e a 2n+1 · · · e a D = 0, (3.30a) ǫ aba 3 ···a DR a 3 a 4 · · ·R a 2n−1 a 2n T 2n+1 e a 2n+2 · · · e a D = 0, (3.30b) whereR ab = R ab + e a e b and T a is the torsion 2−form T a = de a + ω a b e b . The spectrum of solutions of Lovelock and Chern-Simons gravity theories contain (topological) AdS black holes with interesting thermodynamical properties, see e. g. [33,34,35,32,36,37].
We now construct the spinning extension of the black hole solution of the field equations (3.30) found in [36] with planar base manifold. Its line element is given by Skipping the details, the entropy together with the Hawking temperature read , (3.33) while the mass and angular momentum are given by and we easily check that the first law holds. On the other hand, the corresponding soliton derived from the static black hole solution with a double analytic continuation is , and the mass of the soliton is computed to be Finally, the gravitational expression of the entropy (3.33) matches perfectly with the Cardylike formula (2.4) with d eff = D − 2 and with the conserved quantities (3.34-3.35). Notice that this matching is far from trivial and deserves a certain attention for the following reason. As said in the introduction, there exists higher-dimensional extension of the Cardy formula that applied for field theory having an AdS dual, the so-called Cardy-Verlinde formula [9]. Nevertheless, as stressed in [38], the Cardy-Verlinde formula fails in general for the Lovelock AdS black holes independently of the topology of the base manifold.

Hyperscaling violation black hole in D dimensions
Up to now, we have only considered cases where the violating exponent is vanishing, θ = 0. Nevertheless, hyperscaling violation black holes are also known in the current literature, see e. g. [39]. It is conjectured that these solutions may have a certain interest in holographic contexts related to condensed matter physics, see e. g. [40] and [41]. For example, solutions with an hyperscaling violation exponent θ = D − 3 can be useful to describe a dual theory with an O(N 2 ) Fermi surface (N being the number of degrees of freedom). Hyperscaling violation black holes can also be an excellent set-up to test the robustness of the Cardy-like formula (2.4) since in this case the effective spatial dimension d eff is not longer equal to D − 2 but will instead depend on the exponent θ. A toy model in order to achieve this task is given by the Einstein-Hilbert action with a self-interacting scalar field whose field equations read Indeed, for a Liouville potential of the form a static hyperscaling violation black hole was found in [42] with a generic value of the exponent θ, and whose effective spatial dimension is d eff = D − 2 − θ.
As done previously, we construct the spinning extension of the solution [42] that reads where Since the thermodynamics analysis is quite similar to the case of the scalar field with a superrenormalizable potential, we only sketch briefly the quantities of interest as the entropy and temperature of the solution , (3.40) and hence the effective spatial dimensionality d eff = D − 2 − θ. The mass and angular momentum of the solution are given by On the other hand, the corresponding soliton is described by the following line element with the metric function and the scalar field given by The mass of the soliton obtained through the quasilocal charge expression (1.2) reads and it is straightforward to check that the Cardy-like formula (2.4) with d eff = D − 2 − θ fits perfectly with the gravitational entropy (3.40).

Hyperscaling violation black hole with higher-order gravity theory
As said before, the effective spatial dimensionality d eff is not always equal to D − 2 − θ but may have a different expression depending on the theory considered. Nevertheless, in order to corroborate the Cardy-like formula with a different value of the effective dimension, we opt for a pure quadratic gravity theory defined by the action with field equations given by After a straightforward computation, one can see that the field equations admit the line element (3.39) with θ = D − 1 with the metric functions given by , and, where the coupling constants are tied as The entropy and temperature of the solution are given by (3.46) which imply that the effective dimension is d eff = D/(D − 2). Without giving more details, we just report the usual quantities of interest and again, we constat the perfect matching between the gravitational entropy and the Cardylike formula (2.4).

Testing the Cardy-like formula in the anisotropic case
We now consider the anisotropic case which corresponds to a dynamical exponent z = 1 with our convention. In the static case, the asymptotic metric of anisotropic (Lifshitz or hyperscaling violating) black holes can be described by the following line element where now z = 1 is responsible of the anisotropy between the time and the space coordinates.
In spite of the fact that the Cardy-like formula (2.4) is also appropriate with z = 1, stationary anisotropic black hole solutions are not known in the literature. Moreover, unlike the isotropic case, the Lorentz boosts are not longer symmetries for spacetimes with z = 1, and hence the usual trick of performing a Lorentz boost to the static solution may yield to a metric with a rather obscure causal structure. These are the reasons for which we will first concentrate on static anisotropic black holes (J = 0) in order to test the consistency of the formulas (2.4-2.5). Nevertheless, in the last subsection, we will observe the effect on turning on the momentum of a static Lifshitz black hole by the usual Lorentz transformation. Making abstraction of the causal structure, we will compute the mass and angular momentum of the resulting metric and see explicitly that the Cardy-like formula with J = 0 is still consistent with the gravitational entropy.

Lifshitz black holes with higher-order gravity theories
We now deal with a gravity action in arbitrary dimension D with quadratic-curvature corrections given by The corresponding field equations read In Ref. [43], three families of Lifshitz black hole solutions were found. In the present case, we are only interested on the family for which the dynamical exponent z > −(D − 2) and described by the following line element 2 The coupling constants ensuring the existence of this solution can be found in [43]. For this family of solution, the entropy and temperature are (4.7) Since the field equations are of higher order, we find more convenient to adopt the quasilocal formalism in order to compute the mass. This will correspond to the charge Q defined in (1.2) with a Killing vector field ξ t = ∂ t . In the present case, the tensor P αβγδ appearing in the charge formula (1.2) is given by After a tedious but straightforward computation, one obtains the expression of the mass As usual, the corresponding static soliton is and its mass is computed to be It is interesting to note again that the expression of the entropy (4.5) coincides with the Cardy-like formula with d eff = D − 2, J = 0 and for any value of the dynamical exponent z.

Charged anisotropic black holes with two Abelian gauge fields
In this subsection, we would like to check the charged version of the Cardy-like formula (2.5) in the anisotropic and static situation, z = 1 and J = 0. In order to achieve this task, one considers the case of Einstein gravity with two abelian fields A (i) and a dilaton φ with action with F 2 (i) = F (i)µν F µν (i) for i = 1, 2. For the following ansatz

12)
a solution was found in [44]

Turning on the angular momentum
We now turn on the angular momentum of the solution discussed in Sec. 4.1 by operating a standard Lorentz transformation The resulting metric reads where As already mentioned, the resulting metric may suffer some pathology essentially due to the fact that the combination r 2 − r 2z H(r)ω 2 is not ensured to be positive for any value of r > 0 as it is the case in the isotropic situation z = 1. Nevertheless, making abstraction of this problem, one can still compute the entropy and temperature of the solution where Q(z) is defined in (4.7). One of the advantage of the quasilocal formalism [22,23] is precisely to overcome the difficulty at infinity by introducing a one-parameter and by integrating in the interior region and not at infinity. Since the asymptotic form of the resulting metric (4.17-4.18) is not clear, the quasilocal formalism seems to be very-well appropriated to circumvent this problem. In doing so, one can compute the mass and the angular momentum Finally, it is somehow appealing that the Cardy-like formula (2.4) with the angular momentum turning on still reproduces the correct value of the gravitational entropy.

Summary and concluding remarks
Here, we have considered rotating (an)isotropic black holes in arbitrary dimension with a planar horizon which are obtained from static configurations through a Lorentz transformation. The aim of this paper is to show that the spinning black hole entropy can be obtained from the microcanonical degeneracy of states according to a Cardy-like formula making no reference to any central charge but instead involving the mass of the ground state. The ground state is in fact identified with a gravitational bulk soliton. Hence, one of our working hypothesis in order to reproduce the semiclassical black hole entropy is the existence of a soliton. From a technical perspective, the soliton, in all the examples we have treated, is obtained from the static black hole by a double analytic continuation followed by a suitable rescaling that permits to absorb the constant of integration. This procedure is quite similar to the one that yields the AdS soliton [18]. In doing so, the resulting solitonic solution turns to be smooth, regular and devoid of any constant of integration fulfilling what the ground state is expected to be. However, there exist black hole solutions for which the double Wick rotation does not apply for different reasons. For example, this can occur for black holes for which the topology of the event horizon presents an anisotropic scaling symmetry. Such examples have been known much before the advent of Lifshitz spacetimes [45]. In this reference, two families of static black holes solutions of Einstein equations in five dimensions with a negative cosmological constant were constructed, and the horizon topologies of these solutions are modeled by the Solv 3−geometry and the Nil 3−geometry. These geometries are two of the eight geometries of the Thurston classification. The Solv (resp. the Nil) solution is asymptotically AdS (resp. Lifshitz with z = 3/2) but both solution enjoys an anisotropy along one of the coordinates of the event horizon responsible of the violation of the hyperscaling property. On one hand, a simple calculation shows that the Cardy-Verlinde formula [9] for the Solv solution does not yield the correct temperature dependence. On the other hand, while the Solv solution fits perfectly our assumptions, some complications have emerged concerning the Nil solution, in particular to construct the corresponding soliton. An interesting task will consist in understanding what would be the soliton configuration for the Nil solution or how to construct it (even numerically). One can go further extending the analysis done in this paper to the many examples of black holes with Thurston horizon topology.
Another aspect that may deserve some attention in the future has to do with the Smarr formulas. These latter are relations expressing the mass as a simple bilinear form involving the other conserved charges and the thermodynamical quantities [46]. Smarr relations can also be viewed as the integral forms of the first law of thermodynamics. For example, in all the cases studied in this paper, the solutions satisfy a Smarr relation given generically by In the case of asymptotically AdS black holes, extended versions of the first law and of the Smarr formula have been obtained where the cosmological constant is considered as a thermodynamic variable, see e. g. [47]. In this perspective, the mass of the AdS black hole may be understood as the enthalpy of spacetime while the cosmological constant plays the role of a pressure term in the first law. Recently, these ideas have been shown to hold also for Lifshitz black holes [48]. Since Smarr and Cardy formulas are intimately linked, it will be interesting to identify the physical implications on the Cardy-like formulas of viewing the mass as enthalpy.
Finally, we expect that the survey operating in this paper, apart from confirming the validity of the Cardy-like formulas, will be of relevance in order to clarify some issues concerning the field theory side.