On hvLif-like solutions in gauged Supergravity

We perform a thorough investigation of Lifshitz-like metrics with hyperscaling violation (hvLif) in four-dimensional theories of gravity coupled to an arbitrary number of scalars and vector fields, obtaining new solutions, electric, magnetic and dyonic, that include the known ones as particular cases. After establishing some general results on the properties of purely hvLif solutions, we apply the previous formalism to the case of \mathcal{N}=2, d=4 Supergravity in the presence of Fayet-Iliopoulos terms, obtaining particular solutions to the t^3-model, and explicitly embedding some of them in Type-IIB String Theory.


Introduction
Gauge/gravity duality has been shown to be an instrumental tool to study strongly coupled systems near critical points where the system displays a scaling symmetry. Generically, conformal field theories provide consistent descriptions of certain physical systems near critical points. In the gauge/gravity avatar this means that the gravitational theory is living on a background which is asymptotically locally anti De Sitter (aDS). On the other hand, in many physical systems critical points are dictated by dynamical scalings in which, even though the system exhibits a scaling symmetry, space and time scale differently under this symmetry. A prototype example of such critical points is a hyperscaling violating Lifshitz fixed point where the system is spatially isotropic and scale covariant, though there is an anisotropic scaling in the time direction characterized by a dynamical exponent, z, and hyperscaling violation characterized by the exponent θ. More precisely the system is covariant under the following scale symmetry  x i → λx i , t → λ z t, r → λr, ds 2 d+2 → λ 2θ/d ds d+2 , (0.1) where λ is a dimensionless parameter and d is the number of spatial dimensions on which the dual theory lives (i = 1, · · · , d). The value θ = 0 corresponds to the standard scale-invariant theories dual to Lifshitz metric [24][25][26][27][28][29]. The values z = 1 and θ = 0 correspond to conformally-invariant theories dual to gravity theories on an aDS background. For other values of z and θ, the d + 2-dimensional gravitational backgrounds are supported by metrics of the form where is the Lifshitz radius . As usual, we will refer to these metrics as hyperscaling-violating Lifshitz (hvLif ) metrics. The Lifshitz-type spacetimes are known to be singular in the IR. They suffer from a null singularity with diverging tidal forces [30][31][32][33][34][35][36][37][38][39][40][41][42]. For holographic related applications, see [43][44][45][46][47][48][49][50][51][52][53][54].
It is interesting to obtain new gravitational solutions that may be used as duals of the corresponding field theories, if any. A first step on this direction, for N = 2, d = 4 ungauged Supergravity was taken in [55], where a complete analysis on the existence of such kind of solutions was performed. In this note we extend the systematic study to a general class of gravity theories coupled to scalars and vectors, up to two derivatives, in the presence of a scalar potential, in principle arbitrary, focusing later on N = 2, d = 4 Supergravity in the presence of Fayet-Iliopoulos terms.
The structure of the paper goes as follows: in section 1 we dimensionally reduce the general action of gravity coupled to an arbitrary number of scalars and vectors in the presence of a scalar potential assuming a general static background which naturally fits the anisotropic scaling properties which correspond to hvLif -like solutions. In section 2 we adapt the general formalism to the Einstein-Maxwell-Dilaton system. In section 3 we focus on N = 2, d = 4 Supergravity in the presence of Fayet-Iliopoulos terms (which correspond to include a scalar potential in ungauged Supergravity), were we exploit the symplectic structure of the theory in order to obtain further results. We also embed a particular truncation of the t 3 -model in Type-IIB String Theory compactified on a Sasaki-Einstein manifold times S 1 . In section 4 we perform an analysis of the properties of purely hvLif solutions for the general class of theories considered. In addition, we provide a general recip to obtain hvLif -like solutions of a particular class of Einstein-Maxwell-Dilaton systems, reducing the problem to the resolution of an algebraic equation. We apply the procedure to obtain explicit solutions, some of them embedded in String Theory. In section 5 we conclude.

The general theory
We are interested in Lifshitz-like solutions with hyper-scaling violation (hvLif 1 ) of the four-dimensional action that generalizes the action considered in Ref. [56,57] by including a generic scalar potential V (φ). We will take care of the constraints imposed by N = 2 supersymmetry on the field content, the kinetic matrices (I ΛΣ (φ) < 0, R ΛΣ (φ)), the scalar metric G ij (φ) and the scalar potential V (φ) later on.
The idea now is to dimensionally reduce the action (1.1) using an appropriate ansatz for the metric. Since hvLif solutions are in particular static, a first step is to constrain the form of the metric to be A sensible choice for γ, that fits the anisotropic scaling properties that we look for in a hvLif solution, is given by where e W is an undetermined function of the "radial" coordinate r. We now proceed to dimensionally reduce the lagrangian (1.1) with the choice of metric given by Eqs. (1.2) and (1.3).
Assuming that all the fields are static, only depend on r, and following the same steps as in Refs. [56,58] 2 , one arrives to a set of equations of motion for the variables U (r), W (r), φ i (r) that can be derived from the following effective action = d if we set the value of the Hamiltonian (which is conserved, due to the lack of explicit r-dependence of the Lagrangian) to zero, that is: The black-hole potential V bh is defined as in the asymptotically-flat case by [56,58,63] where α is a normalization constant for the electric and magnetic charges 3 1 We will understand for hvLif any non-trivial gravitational solution that presents some kind of Lifshitz limit with hyper-scaling violation. Purely hvLif stands for metrics that are exactly Lifshitz with hyper-scaling violation. 2 A related procedure, used to obtain non-extremal aDS 4 black hole solutions can be found in [59] and [60]. For related Refs. about solutions in gauged Supergravity see [61,62]. 3 The canonical choice for d = 4 is α = 1 2 .
and where the symmetric matrix M M N is defined in terms of I ≡ (I ΛΣ ) and R ≡ (R ΛΣ ) by The one-dimensional effective equations of motion are given by 4 to which we have to add the Hamiltonian constraint (1.5). The kinetic term for the scalars, as well as the scalar potential V (φ) and the black hole potential V bh (φ, Q), can be solely expressed in terms of U and W, i.e., Eqs. (1.14) are useful in order to obtain, given a particular metric, the behavior of different quantities, like V (φ) and V bh (φ, Q), or φ i for models with small enough number of scalars, in terms of the coordinate r.
Of course, only metrics compatible with the equations of motion will yield consistent results.

Constant scalars: generalities
For constant scalars φ i , the potential V (φ) and the black hole potential V bh (φ, Q) become constant quantities, the former playing the role of a cosmological constant and the latter of a generalized squared charge, magnetic and electric. In the case of constant scalars, Eq. (1.13) is not identically satisfied, but it becomes the following constraint We have two different options in order to fulfil Eq. (1.15). 4 The form of the vector fields can be recovered following the dimensional-reduction procedure. The corresponding field strengths F Λ µν are given by where Ψ = (ψ Λ , χ Λ ) T is a symplectic vector whose components are the time components of the electric A Λ and magnetic A Λ vector fields. Ψ is given by Constant scalars as double critical points: ∂ i V bh = 0, ∂ i V = 0. Of course, the system of equations given by is overdetermined. However, let's assume that a consistent solution to (1.16) exists and is given by i.e., the values of the scalars are fixed in terms of the electric and magnetic charges, and we have included a dependence on φ ∞ to formally consider the existence of flat directions. We will see later on that, in fact, Eq. (1.16) happens in N = 2, d = 4 Supergravity. The equations of motion reduce to together with the hamiltonian constraint In this case, the equations of motion imply Assuming Eqs. (1.21), there is a unique solution, which is precisely aDS 2 × R 2 . Eqs. (1.21) can be understood as necessary and sufficient conditions for a gravity theory coupled to scalars and vector fields, up to two derivatives, to contain an aDS 2 × R 2 solution. Therefore, given a particular theory of such kind, with a specific potential V (φ) and black hole potential V bh (φ), one only has to impose Eqs. (1.21) in order to check the existence of an aDS 2 × R 2 solution. The parameter β can be always found to be and we are left with Eq. (1.23) is a system of n v equations for at least n v variables (the n v constant scalars), and hence in general it will be compatible and the theory will contain an aDS 2 × R 2 solution. Only in pathological cases the system (1.23) will be incompatible and the theory will fail to contain an aDS 2 × R 2 solution.

The Einstein-Maxwell-Dilaton model
Before we discuss the possible embeddings of Eq. (1.1) in gauged Supergravity and String Theory, let's consider the Einstein-Maxwell-Dilaton (E.M.D.) system, whose action is characterized by the following choices, to be made in Eq. (1.1) Hence, the E.M.D. action reads i.e., we consider a single vector field and a single scalar field. Moreover, the coupling given by R is taken to be zero, which greatly simplifies the black hole potential V bh (φ, Q), which is therefore given by where q and p are the electric and magnetic charges, respectively. The equations of motion take the form and the hamiltonian constraint reads and Z is such that Theories with conventional and sensible matter have to satisfy the null-energy condition (NEC) n µ n ν T µν ≥ 0, where n µ is an arbitrary null vector and T µν is the correspondent energy-momentum tensor. This condition translates, for the E.M.D. case, into the following constraints Hence, it is equivalent to the requirement of a semi-negative definite black hole potential, and a semipositive definite kinetic term for the scalar field, compatible with the condition Z (φ).

Another coordinate system:
There is another system of coordinates which we will use along this paper, and that will be useful for different purposes. It is related to the U − W system of coordinates by the following identifications: giving rise to the metric which has proven to be useful (see e.g. [2], [64]) in order to obtain solutions exhibiting hvLif asymptotics when f (r) is a function ofr that obeys The hvLif limit is, thus, assumed to be atr 0 , whereas the horizon is atr h . The equations of motion (2.4), (2.5) and (2.6) can be rewritten accordingly as 5 The Hamiltonian constraint is given by Again, for non-constant dilaton this set of equations is equivalent to 6 The action (1.1) has great generality and basically covers any possible theory of gravity coupled to abelian vector fields and scalars up to two derivatives. However, in order to embed our results in String Theory, it is convenient to focus on the bosonic sector of N = 2, d = 4 Supergravity, which is a particular case of (1.1). More precisely, we are going to consider gauged N = 2, d = 4 in the presence of n v abelian vector multiplets, where the gauge group is contained in the R-symmetry group of automorphisms of the supersymmetry algebra. Normally one refers to this theory as N = 2, d = 4 Supergravity with Fayet-Iliopoulos terms (from now on, N = 2 FI to abridge) [65]. The general lagrangian of N = 2 FI is given by The indices i, j, . . . = 1, . . . , n v run over the scalar fields and the indices Λ, Σ, . . . = 0, . . . , n v over the 1-form fields. The scalar potential generated by the F.I. terms reads where K is the Kähler potential, Z g is given by 7 and the g M is a symplectic vector related to the embedding tensor θ M , that selects the combination of vectors that gauges U (1) ⊂ R-symmetry group, as follows 8 g being the gauge coupling constant. The corresponding one-dimensional effective action and the hamiltonian constraint are given, respectively, by The black-hole potential takes the simple form where is the central charge of the theory.
Constant scalars and supersymmetric attractors. In section (1) we studied the case of constant scalars in the general theory (1.1). We found that, besides the solution aDS 2 × R 2 , there was another possible solution, if Eq. (1.16) holds. We will see now how this is always possible in N = 2 FI. The general theory of the attractor mechanism in ungauged d = 4 Supergravity proves that, for extremal black holes, the value of the scalars at the horizon is fixed in terms of the charges Q M , and given by the so called critical points or attractors, i.e., solutions to the system There might be some residual dependence in the value at infinity if the potential has flat directions. If the scalars are constant, they have to be given again by (3.9) in the extremal as well as in the non-extremal case. It can be proven that there is always a class of attractors, called supersymmetric, which obey and therefore, given the definitions (3.2) and (3.7), they also obey (1.16) if Q M ∼ g M . Hence, setting the scalars to constant values given by the supersymmetric attractor points of the black hole potential is always a consistent truncation, provided that g M is identified with Q M , which besides fixes the value of the black hole potential and the scalar potential exclusively in terms of the charges.

The t 3 -model
In this section we consider a particular N = 2 FI model which can be embedded in String Theory. In particular we start from Type-IIB String Theory compactified on a Sasaki-Einstein manifold to five dimensions. This theory can be consistently truncated as to yield pure N = 1, d = 5 Supergravity with Fayet-Iliopoulos terms, which, due to the absence of scalars, introduce a cosmological constant. Further compactification on S 1 gives us the desired four dimensional theory, which is defined by [67][68][69][70] n where β 2 = g 2 1 /3, and we have defined the inhomogeneous coordinate on the Special Kähler manifold This theory is known as the t 3 -model, and although the String Theory embedding requires the gauging specified in Eq. (3.11), we are going to study it in full generality, particularizing only at the end. The canonically normalized symplectic section V is, in a certain gauge, where the Kähler potential is (3.14) As a consequence, the Kähler metric reads 15) and the central charge The period matrix N IJ is, in turn, given by where we use the notation: ≡ et, ≡ mt. The general expressions of V bh and V fi , which can be obtained using Eqs.
Let's consider the truncation et = 0. In order to satisfy all the original equations of motion (those with et arbitrary) in such a case, we must impose the additional constraints These conditions explicitly read and are satisfied (without loss of generality in the functional form of the potentials) if we make Thus, setting et to zero in a consistent manner notably simplifies the expressions for the potentials The action is, making the redefinition t ≡ + ie − φ √ 3 , given by where we have already set A 1 µ to zero, in order to make the truncation consistent with the corresponding equation of motion.
Embedding the t 3 -model system in the E.M.D. As it can be trivally verified, we have just obtained the action (2.2) with 28) and the scalar potential of the E.M.D. system (Eq. (4.31)) given by Hence, we find that our axion-free t 3 -system with those particular choices of Z and V gets embedded in the E.M.D. model and, for g 0 = g 1 = g 0 = 0, also in String Theory in the way explained at the beginning of this section. In such a case, Eq. (3.26) clearly becomes . (3.30)

hvLif solutions
In this section we are going to construct (purely and asymptotically) hvLif solutions to Eq. (1.1). After establishing some results on the properties of the solutions corresponding to the pure hvLif case in the general set-up of Eq. (1.14), we focus on the E.M.D. system, obtaining the hvLif solutions allowed by the embedding of our axion-free Supergravity model in this system. Then, we provide a recipe to construct asymptotically hvLif solutions to these theories in the presence of constant and non-constant dilaton fields, recovering and extending some of the results already present in the literature.

(4.2)
For purely hvLif solutions, the equations of motion can be further simplified by direct substitution of (4.2) The Hamiltonian constraint reads Eqs. (1.14) can be also adapted to the purely hvLif case. We find where (4.10) Eqs. (4.3)-(4.6) are the general equations of motion that need to be solved in order to find a hvLif solution to any theory that belongs to the class defined by Eq. (1.1). Likewise, Eq. (4.7) provides the behaviour of the black hole potential and the scalar potential, in terms of the variable r, for any hvLif solution consistent with the equations of motion. G ij is positive-definite, therefore and hence we can establish the following result: all the scalar fields of any purely hvLif solution of any theory describable by Eq. (1.1) are constant iff θ = 2, or z = 1 + θ/2. In addition, V bh is, in our conventions, a negative definite function, hence V bh ≤ 0 ⇔ Y (θ,z) ≤ 0. These two conditions on the sign of W (θ,z) and Y (θ,z) are equivalent to imposing the null-energy condition (NEC) to our purely hvLif solutions, as we commented before, and define a region of acceptable solutions in the (θ, z)-plane, as we shall see.
It is possible to stablish some general results for the hvLif solutions of any theory describable by Eq. (1.1) attending to the vanishing of V , V bh and/or G ijφ iφj . Let's proceed.
We have again G ijφ iφj = 0, and 14) The NEC translates into θ ∈ [0, 6], and we have three more special cases: the Ricci flat one: θ = 6, z = 4 corresponding to V = V bh = 0 (this is a particular case of the general formalism developed in [55] for ungauged N = 2, d = 4 Supergravity); θ = 4, z = 3, which corresponds to V = 0, V bh = − 2 (also in agreement with the results of [55]); and θ = 0, z = 1, which is nothing but the aDS 4 spacetime in a conformally flat representation, and the only solution with vanishing black hole potential, and constant (non-zero) scalar potential compatible with the equations: V bh = 0, V ≡ Λ = − −2 6.
Another particularly interesting case corresponds to the Einstein-Maxwell system with a cosmological constant: G ijφ iφj = 0, V ≡ Λ. However, this could only be realized for θ = 0, z = 1, which imposes the vanishing of V bh . Hence, there is no purely hvLif solution (for non-vanishing vector fields) for such model.  If we particularize now to the E.M.D. system, we find Therefore, V and V bh written as functions of φ, must take the form This means, on the one hand, that any E.M.D. theory susceptible of containing hvLif solutions has a scalar potential which depends on φ through one single exponential (becoming a constant when θ = 0, θ = 2 or z = 1 + θ/2 (φ = φ 0 in the last two cases)) [17]. On the other hand, the gauge coupling function is constant for θ = 4, and again if φ = φ 0 . . In I there exists one only solution, which is magnetic, and corresponds to θ = −2, z = 3/2, g 2 1 = 297/(4 2 ) and p 2 = 11 2 /4. On the other hand, case II admits one only solution (magnetic as well) for θ = 1, z = 3, g 1 2 = 4/ 2 , and p 2 = 8 2 . Both solutions satisfy the NEC, as it was desirable, and have a running dilaton given by Eq. Υ and V , in turn, become 9 In order to tackle the problem of constructing asymptotically hvLif metrics, and taking into account the form of V (φ) and Z(φ) for our axion-free model (and others present in the literature), we can start by considering these functions to have the generic form (4.32) The form of V (φ) is motivated by the expression of V fi appearing in the axion-free t 3 model, as well as in other String Theory truncations present in the literature (see, e.g. [71], [72]). On the other hand, additional terms to the single-exponential gauge coupling have been introduced to mimic the quantum corrections appearing from String Theory (see, e.g. [73]), in an attempt to cure the logarithmic behavior of the dilaton, which blows up in the deep IR, pointing out the non-negligibility of quantum corrections in this regime.
The expressions for V (φ) and Z(φ) can be introduced in Eqs. (4.29) and (2.10), (2.11) or (2.12) (depending on whether we are searching for electric, magnetic or dyonic solutions) using Eq. (4.30). Once this is done, we are left with two second-order differential equations for f (r) which can in general be converted into a first order equation plus a constraint that remains to be fulfilled. Obtaining the general solution in the presence of so many arbitrary parameters (c 1 , c 2 , c 3 , d 1 , d 2 , d 3 , s 1 , s 2 , t 1 , t 2 , z and θ) seems not to be possible and therefore we are forced to consider further simplifications, keeping in mind that the procedure does work for other set-ups in which Z(φ) and V (φ) are given by a different choice of the parameters in (4.31) and (4.32). Taking into account the form of the potentials obtained in the axion-free t 3 model, let's assume s 1 = s 2 , d 2 = d 3 = 0 (we allow t 1 to be positive or negative) (4.34) The general form of the blackening factor, valid in all cases (electric, magnetic and dyonic), reads where ∆ = (θ − 2)(θ − 2z + 2), K is an integration constant, and (4.40) As we said, there is an additional (non trivial) constraint to be satisfied (4.41) At this point, there are several ways to construct solutions. On the one hand, it is possible to impose values to z and θ and find the corresponding potentials admitting solutions for particular blackening factors. On the other hand, it is possible to fix the coefficients in the exponents of Z and V and find the blackening factors allowed by Eq. (4.41). We will proceed along the lines of the second possibility, looking for solutions embedded in the Supergravity t 3 model. Before doing so, let's consider the general case in which the exponents in Z(φ) and V (φ) are such that s 1 = θ/∆, t 1 = (4 − θ)/∆, and c 2 = q = 0. The result is a family of solutions for arbitrary values of z and θ determined by which is well known (see, e.g. [64], [72], [54]) The same family can also be found for electric solutions setting s 1 = θ/∆, t 1 = (θ−4)/∆, and c 1 = p = 0.
In that case, the solution is given by It turns out that setting q = 0, it is possible to construct two families of solutions which, in the apropriate cases, asymptote to the purely hvLif ones constructed in the previous subsection. The first one is determined by where A is a constant depending on z and θ. The blackening factor is given by where C is another z, θ-dependent constant. Needless to say, the metric will not, in general, asymptote to a hvLif (with exponents z, θ) as r → 0 except for particular values of θ and z. However, if we choose θ = −2, z = 3/2, c 2 = −9p 2 , we find The second family is characterized by where A is another constant, and the blackening factor reads which, as we will see in a moment, is a particular a case of a dyonic solution admitted by the model.

Electric solutions.
Similarly, we can construct two families of electric solutions. The first one is characterized by where, once more, A is a constant depending on z and θ. The blackening factor is given by whereas for the second In contradistinction to the magnetic cases, for no values of (θ, z) the above solutions take the form of Eq. (4.44). This is obviously connected to the fact that no purely hvLif electric solutions exist in this model for non-constant dilaton and scalar potential, as we saw before.
3. Dyonic solutions. It is possible to show that a dyonic solution does exist for θ = 1, z = 3, c 2 = 0, and c 1 = −3p 2 /2, with a blackening factor given by The corresponding metric Eq.(2.16) reads (after the redefinitions dR 2 = 8dr 2 /p 2 , dT 2 = 8dt 2 /p 2 ) (4.58) It asymptotes to a hvLif as R → 0 with θ = 1, z = 3, and to a different one as R → ∞ with θ = 5/2, z = 3/2 as it can be seen by taking the limit in the previous expression, and defining ρ ∼ R −2 which corresponds to θ = 5/2, z = 3/2. The value of K can be fixed in a way such that ∃ R h ∈ R + / f (R h ) = 0, or chosen to get a positive-definite metric in the whole spacetime.
In the previous section, we constructed two consistent truncations of this model (which we called "I" and "II"). The first one is such that c 2 = 0 ⇒ c 1 = 0, and hence the solution can be embedded in that model only for a vanishing V fi and magnetic charge. For the second, in turn, we get the conditions g 0 = 0, g 1 2 = p 2 /2. It is interesting to investigate how the solution gets modified by turning off the electric or the magnetic charge. Obviously, setting q = 0 does not change the R → 0 behavior, but does change the R → +∞ one. In such a case, the metric becomes which is conformal to Minkowski, and corresponds to a hvLif with θ = 3, z = 1. On the other hand, restoring q and setting p = 0, imposes the vanishing of V fi , and the solution is θ = 3, z = 1 as R → 0, and again θ = 5/2, z = 3/2 as R → +∞.

Constant scalar field
Let's consider now the case of a constant scalar field, φ = 0. As explained in section 1, we consider In this case, the potential and the coupling become constant and we can write V = Λ, Z = −Z 2 0 . When Z and V are given by Eqs. (4.32) and (4.31), Eq. (4.65) translates into where we have imposed φ = 0 to be a critical point of the potentials. We choose to fulfill the first condition demanding (d 1 + d 2 ) 2 = q 2 /p 2 which, when d 1 = 0, reads d 2 = −|q/p|. On the other hand, the second condition is s 1 c 1 = s 2 c 2 , that becomes c 1 = c 2 when both exponents (s 1 and s 2 ) coincide. After imposing these constraints, V and Z become We have two cases: z = 1 + θ/2 and θ = 2 (and the one in the intersection: z = 2, θ = 2).
1. z = 1 + θ 2 , θ = 2. In this situation, it is possible to find a solution which imposes no further constraints on V and V bh . This reads (4.70) The case z = 1, θ = 0, in which we expect to recover aDS 4 asymptotically is a particularization of this. The blackening factor reads then which, of course, asymptotes to aDS 4 as R → 0, and is such that Similarly, the metric blows up as R → ∞, behaving as a hvLif with θ = 4, z = 3. Indeed, up to constants; if we make now the change ρ ∼ 1/R we find a hvLif metric with θ = 4, z = 3 as we have said. If we plug these values θ = 4, z = 3 in Eq. (4.70) we find a new solution, which behaves asymptotically as this one (with the IR and U V regions interchanged). Indeed, its blackening factor reads and with the redefinitions (4.77) As R → 0, it becomes a hvLif with θ = 4, z = 3, and as R → ∞, which we can rewrite as (ρ = 1/R) which is aDS 4 .

Conclusions
We have studied purely hvLif and hvLif -like solutions of the general class of theories defined by the Lagrangian (1.1), which covers any theory of gravity coupled to an arbitrary number of scalars and vector fields up to two derivatives. We have obtained the general effective one-dimensional equations of motion that need to be solved in order to obtain hvLif -like solutions.
The general analysis is intended to complete the case-by-case results present in the literature in a unified framework: given a particular kinetic matrix (I ΛΣ (φ), R ΛΣ (φ)), a scalar metric G ij (φ) and a scalar potential V (φ), the equations of motion of the theory follow trivially by plugging them into (1.11)-(1.13) and the Hamiltonian constraint (1.5).
For this broad family of theories, we have discussed the existence and properties of purely hvLif solutions attending to the presence (or absence) of non-constant scalar fields and non-vanishing black hole and scalar potentials.
In the context of N = 2 FI Supergravity, we have studied the t 3 -model, for which we have explicitly constructed two consistent axion-free embeddings in the E.M.D. system, one of which is, in turn, embedded in Type-IIB String Theory for a particular choice of embedding tensor θ M .
In addition, we obtained the general form of the f (r) function (for the set of metrics determined by Eqs. (4.27) and (2.16)), up to a constraint, for a rather general family of (Supergravity inspired) scalar and black-hole potentials, and explicitly constructed some dyonic solutions for the t 3 truncations considered. We have provided a straightforward procedure to construct asymptotically hvLif solutions covered by Eqs. We have avoided, on purpose, the term black hole to denote the hvLif -like solutions obtained in this paper. The reason is that, although they look like black holes, a complete and rigorous proof (for example by constructing the corresponding Penrose-Carter diagram) is still missing. Therefore, any results obtained from them implicitly assuming that they do represent a black hole must be interpreted carefully, knowing that those would be yet to be proven statements.
As a final remark, we would like to point out that, thanks to the BH-hvLif-Topological triality (BHvTriality) discovered in [55], the new fascinating results that are being obtained in the context of static, spherically symmetric black holes in ungauged N = 2, d = 4 Supergravity [74][75][76][77][78][79] can also be applied to hvLif, giving therefore, the first examples of hvLif -like solutions in the presence of quantum corrections induced by Type-IIA String Theory Calabi-Yau compatifications.
Note added: During the very last stage of this project, the very interesting Ref. [80] appeared, containing a minor overlap with our work.