Abstract

We construct an effective four-dimensional model by compactifying a ten-dimensional theory of gravity coupled with a real scalar dilaton field on a time-dependent torus. This approach is applied to anisotropic cosmological Bianchi type I model for which we study the classical coupling of the anisotropic scale factors with the two real scalar moduli produced by the compactification process. Under this approach, we present an isotropization mechanism for the Bianchi I cosmological model through the analysis of the ratio between the anisotropic parameters and the volume of the Universe which in general keeps constant or runs into zero for late times. We also find that the presence of extra dimensions in this model can accelerate the isotropization process depending on the momenta moduli values. Finally, we present some solutions to the corresponding Wheeler-DeWitt (WDW) equation in the context of standard quantum cosmology.

1. Introduction

The 2015 release of Planck data has provided a detailed map of cosmic microwave background (CMB) temperature and polarization allowing us to detect deviations from an isotropic early Universe [1]. The evidence given by these data leads us to the possibility of considering that there is no exact isotropy, since there exist small anisotropy deviations of the CMB radiation and apparent large angle anomalies. In that context, there have been recent attempts to fix constraints on such deviations by using the Bianchi anisotropic models [2]. The basic idea behind these models is to consider the present observational anisotropies and anomalies as imprints of an early anisotropic phase on the CMB which in turn can be explained by the use of different Bianchi models. In particular, Bianchi I model seems to be related to large angle anomalies [2] (and references therein).

In a different context, attempts to understand diverse aspects of cosmology, as the presence of stable vacua and inflationary conditions, in the framework of supergravity and string theory have been considered in the last years [310]. One of the most interesting features emerging from these types of models consists in the study of the consequences of higher dimensional degrees of freedom on the cosmology derived from four-dimensional effective theories [11, 12]. The usual procedure for that is to consider compactification on generalized manifolds, on which internal fluxes have back-reacted, altering the smooth Calabi-Yau geometry and stabilizing all moduli [10].

The goal of the present work is to consider in a simple model some of the above two perspectives; that is, we will consider the presence of extra dimensions in a Bianchi I model with the purpose of tracking down the influence of moduli fields in its isotropization. For that we will consider an alternative procedure concerning the role played by moduli. In particular we will not consider the presence of fluxes, as in string theory, in order to obtain a moduli-dependent scalar potential in the effective theory. Rather, we are going to promote some of the moduli to time-dependent fields by considering the particular case of a ten-dimensional gravity coupled to a time-dependent dilaton compactified on a 6-dimensional torus with a time-dependent Kähler modulus. With the purpose to study the influence of such fields, we are going to ignore the dynamics of the complex structure modulos (for instance, by assuming that it is already stabilized by the presence of a string field in higher scales). This will allow us to construct classical effective models with two moduli.

However, we are also interested in possible quantum aspects of our model. Quantum implications on cosmology from more fundamental theories are expected due to different observations. For instance, it has been pointed out that the presence of extra dimensions leads to an interesting connection to the ekpyrotic model [13], which generated considerable activity [8, 9, 14]. The essential ingredient in these models (see, for instance, [11]) is to consider an effective action with a graviton and a massless scalar field, the dilaton, describing the evolution of the Universe, while incorporating some of the ideas of pre-big-bang proposal [15, 16] in that the evolution of the Universe began in the far past. On the other hand, it is well known that relativistic theories of gravity such as general relativity or string theories are invariant under reparametrization of time. Quantization of such theories presents a number of problems of principle known as “the problem of time” [17, 18]. This problem is present in all systems whose classical version is invariant under time reparametrization, leading to its absence at the quantum level. Therefore, the formal question involves how to handle the classical Hamiltonian constraint, , in the quantum theory. Also, connected with the problem of time is the “Hilbert space problem” [17, 18] referring to the not at all obvious selection of the inner product of states in quantum gravity and whether there is a need for such a structure at all. The above features, as it is well known, point out the necessity to construct a consistent theory of gravity at quantum level.

Analyses of effective four-dimensional cosmologies derived from M-theory and Type IIA string theory were considered in [1921] where string fluxes are related to the dynamical behavior of the solutions. A quantum description of the model was studied in [22, 23] where a flat Friedmann-Robertson-Walker geometry was considered for the extended four-dimensional space-time, while a geometry given by was assumed for the internal seven-dimensional space; however, the dynamical fields are in the quintom scheme, since one of the fields has a negative energy. Under a similar perspective, we study the Hilbert space of quantum states on a Bianchi I geometry with two time-dependent scalar moduli derived from a ten-dimensional effective action containing the dilaton and the Kähler parameter from a six-dimensional torus compactification. We find that, in this case, the wave function of this Universe is represented by two factors, one depending on moduli and the second one depending on gravitational fields. This behavior is a property of all cosmological Bianchi Class A models.

The work is organized in the following form. In Section 2 we present the construction of our effective action by compactification on a time-dependent torus, while in Section 3 we study its Lagrangian and Hamiltonian descriptions using as toy model the Bianchi type I cosmological model. Section 4 is devoted to finding the corresponding classical solutions for few different cases involving the presence or absence of matter content and the cosmological constant term. Using the classical solutions found in previous sections, we present an isotropization mechanism for the Bianchi I cosmological model, through the analysis of the ratio between the anisotropic parameters and the volume of the Universe, showing that, in all the cases we have studied, its value keeps constant or runs into zero for late times. In Section 5 we present some solutions to the corresponding Wheeler-DeWitt (WDW) equation in the context of standard quantum cosmology and finally our conclusions are presented in Section 6.

2. Effective Model

We start from a ten-dimensional action coupled with a dilaton (which is the bosonic component common to all superstring theories), which after dimensional reduction can be interpreted as a Brans-Dicke like theory [24]. In the string frame, the effective action depends on two spacetime-dependent scalar fields: the dilaton and the Kähler modulus . For simplicity, in this work we will assume that these fields only depend on time. The high-dimensional (effective) theory is therefore given bywhere all quantities refer to the string frame while the ten-dimensional metric is described bywhere are the indices of the ten-dimensional space and Greek indices and Latin indices correspond to the external and internal spaces, respectively. We will assume that the six-dimensional internal space has the form of a torus with a metric given bywith being a real parameter.

Dimensionally reducing the first term in (1) to four-dimensions in the Einstein frame (see the Appendix for details) giveswhere , with given by By considering only a time-dependence on the moduli, one can notice that, for the internal volume to be small, the modulus should be a monotonic increasing function on time (recall that is a real parameter), while is time and moduli independent.

Now, concerning the second term in (1), we will require properly defining the ten-dimensional stress-energy tensor . In the string frame it takes the formwhere and denote the four- and six-dimensional components of . Observe that we are not considering mixing components of among internal and external components although nonconstrained expressions for have been considered in [25]. In the Einstein frame the four-dimensional components are given byIt is important to remark that there are some dilemmas about what is the best frame to describe the gravitational theory. Here in this work we have taken the Einstein frame. Useful references to find a discussion about string and Einstein frames and its relationship in the cosmological context are [2630].

Now with expression (4) we proceed to build the Lagrangian and the Hamiltonian of the theory at the classical regime employing the anisotropic cosmological Bianchi type I model. The moduli fields will satisfy the Klein-Gordon like equation in the Einstein frame as an effective theory.

3. Classical Hamiltonian

In order to construct the classical Hamiltonian, we are going to assume that the background of the extended space is described by a cosmological Bianchi type I model. For that, let us recall here the canonical formulation in the ADM formalism of the diagonal Bianchi Class A cosmological models; the metric has the formwhere is the lapse function, is a diagonal matrix, , and are scalar functions, known as Misner variables, and are one-forms that characterize each cosmological Bianchi type model [31] and obey the form , with the structure constants of the corresponding model. The one-forms for the Bianchi type I model are , , and . So, the corresponding metric of the Bianchi type I in Misner’s parametrization has the formwhere are the anisotropic radii and they are given by where is the volume function of this model.

The Lagrangian density, with a matter content given by a barotropic perfect fluid and a cosmological term, has a structure, corresponding to an energy-momentum tensor of perfect fluid [3236] that satisfies the conservation law . Taking the equation of state between the energy density and the pressure of the comovil fluid, a solution is given by with the corresponding constant for different values of related to the Universe evolution stage. Then, the Lagrangian density reads while the Lagrangian that describes the fields dynamics is given byusing the standard definition of the momenta, , where , and we obtainand, introducing them into the Lagrangian density, we obtain the canonical Lagrangian as . When we perform the variation of this canonical lagrangian with respect to , , implying the constraint . In our model the only constraint corresponds to Hamiltonian density, which is weakly zero. So, we obtain the Hamiltonian density for this model:We introduce a new set of variables in the gravitational part given by which corresponds to the volume of the Bianchi type I Universe, in similar way to the flat Friedmann-Robetson-Walker metric (FRW) with a scale factor. This new set of variables depends on Misner variables as from which the Lagrangian density (13) can be transformed as and the Hamiltonian density readsSo far, we have built the classical Hamiltonian density from a higher dimensional theory; this Hamiltonian contains a barotropic perfect fluid, that we have added explicitly. The next step is to analyze three different cases involving terms in the classical Hamiltonian (18) and find solutions to each of them in the classical regime.

3.1. Isotropization

The current observations of the cosmic background radiation set a very stringent limit to the anisotropy of the Universe [37]; therefore, it is important to consider the anisotropy of the solutions. We will denote through all our study derivatives of functions with respect to by (the following analysis is similar to this presented recently in the K-essence theory, since the corresponding action is similar to this approach [38]). Recalling the Friedmann like equation to the Hamiltonian densitywe can see that isotropization is achieved when the terms with go to zero or are negligible with respect to the other terms in the differential equation. We find in the literature the criteria for isotropization, among others, , , that are consistent with our above remark. In the present case the comparison with the density should include the contribution of the scalar field. We define an anisotropic density that is proportional to the shear scalar, and will compare it with , , and . From the Hamilton analysis we now see that and the kinetic energy for the scalars fields and are proportional to . This can be seen from definitions of momenta associated with Lagrangian (13) and the above equations. Then, defining as , we have that With the use of these parameters, we find the following ratios: We observe that for an expanding Universe the anisotropic density is dominated by the fluid density (with the exception of the stiff fluid) or by the term and then at late times the isotropization is obtained since the above ratios tend to zero.

4. Case of Interest

In this section we present the classical solutions for the Hamiltonian density of Lagrangian (13) we have previously built in terms of a new set of variables (16), focusing on three different cases. We start our analysis on the vacuum case, and on the case with a cosmological term . Finally we will analyze the general case considering matter content and a cosmological term.

4.1. Vacuum Case

To analyze the vacuum case, we will take in the Hamiltonian density (18) that and , obtaining thatThe Hamilton equations for the coordinates fields and the corresponding momenta becomeThe gravitational momenta are constant by mean of the Hamiltonian constraint, first line in the last equation. In this way, the solution for the sum of functions becomes with and being an integration constant. Therefore, Misner variables are expressed aswhile moduli fields are given by where and . Notice that, in this case, the associated external volume given by and the moduli fields and are all logarithmically increasing functions on time, implying for the latter that the internal volume shrinks in size for late times, as expected, while the four-dimensional Universe expands into an isotropic flat spacetime. The parameter goes to zero at very late times independently of .

4.2. Cosmological Term

The corresponding Hamiltonian density becomesand corresponding Hamilton’s equations arewhere the constants and are the same as in previous case. To solve the last system of equations we will take the following ansatz:with and constants. By substituting into Hamiltonian (29) we find a differential equation for the momenta given by where the corresponding constants are with the constant (related to the momenta scalar field)The solution for is thusHence, using the last result (35) in the rest of equations in (30) we obtain that and the corresponding solutions to the moduli fields are With the last results we see that the solutions to the Misner variables are given by and the isotropization parameter is given by Notice that the external four-dimensional volume expands as time runs and it is affected whether is positive or negative. This in turn determines how fast the moduli fields evolve in relation to each other (i.e., whether is larger or smaller than ). Therefore, isotropization is reached independently of the values of but expansion of the Universe (and shrinking of the internal volume) is affected by it.

4.3. Matter Content and Cosmological Term

For this case, the corresponding Hamiltonian density becomes (18). So, using the Hamilton equation, we can see that the momenta associated with the scalars fields and are constants, and we will label these constants by and , respectively:Follow the same steps as in Section 4.2, we see that it is possible to relate the momenta associated with , , and in the following way:Also, the differential equation for fields and can be reduced to quadrature as

We proceed to consider specific values for .

4.3.1. Cases

Let us introduce the generic parameter for which . Substituting this into Hamiltonian (18) we find the differential equation for the momenta as with the solution given by isOn the other hand, using the last result (45) we obtain from Hamilton equations that The corresponding solutions to the moduli fields (42) can be found asThe solutions to Misner variables (16), , are given byIt is remarkable that (42) for the fields and are maintained for all Bianchi Class A models, and in particular, when we use the gauge , the solutions for these fields are independent of the cosmological models, whose solutions are and .

After studying the case we will comment on the physical significance of these solutions.

4.3.2. Case

The Hamilton equations arefrom which the momenta fulfil the equationwhere The solution is given by Using this result in the corresponding Hamilton equations, we obtain that and the corresponding solutions to the dilaton field and the moduli field are given bySo, the solutions to the Misner variables are

For both solutions, , we also observe that, for positive (negative) , the Universe expands slower (faster) than in the absence of extra dimensions while the internal space shrinks faster (slower) for positive (negative) . In this case, isotropization parameters are also accordingly affected by , through relations (34).

So far, our analysis has been completely classic. Now, in the next section we deal with the quantum scheme and we are going to solve the WDW equation in standard quantum cosmology.

5. Quantum Scheme

Solutions to the Wheeler-DeWitt (WDW) equation dealing with different problems have been extensively used in the literature. For example, the important quest of finding a typical wave function for the Universe was nicely addressed in [39], while in [40] there appears an excellent summary concerning the problem of how a Universe emerged from a big bang singularity, whihc cannot longer be neglected in the GUT epoch. On the other hand, the best candidates for quantum solutions become those that have a damping behavior with respect to the scale factor, represented in our model with the parameter, in the sense that we obtain a good classical solution using the WKB approximation in any scenario in the evolution of our Universe [41]. The WDW equation for this model is achieved by replacing the momenta , associated with the Misner variables and the moduli fields in Hamiltonian (15). The factor may be factor ordered with in many ways. Hartle and Hawking [41] have suggested what might be called a semigeneral factor ordering which in this case would order aswhere is any real constant that measure the ambiguity in the factor ordering in the variable and the corresponding momenta. We will assume in the following this factor ordering for the Wheeler-DeWitt equation, which becomeswhere is the three-dimensional d’Lambertian in the coordinates, with signature . On the other hand, we could interpret the WDW equation (57) as a time-reparametrization invariance of the wave function . At a glance, we can see that the WDW equation is static; this can be understood as the problem of time in standard quantum cosmology. We can avoid this problem by measuring the physical time with respect a kind of time variable anchored within the system, which means that we could understand the WDW equation as a correlation between the physical time and a fictitious time [42, 43]. When we introduce the ansatzin (57), we obtain the general set of differential equations (under the assumed factor ordering):where we choose the separation constant for convenience to reduce the second equation. The solution to the hyperbolic partial differential equation (60) is given bywhere are integration constants and they are in terms of . We claim that this solution is the same for all Bianchi Class A cosmological models, because the Hamiltonian operator in (57) can be written in separated way as , where y represents the Hamiltonian to gravitational sector and the moduli fields, respectively. To solve (59), we now set , obtaining the following set of ordinary differential equations:where and and are constants. We now focus on the dependent part of the WDW equation. We solve this equation when and .

(1) For the case with null cosmological constant and ,and by using the change of variable,where is a parameter to be determined, we have Hence, we arrive at the equationwhere we have assumed that is of the form [44]with being yet to be determined. We thus get, after substituting in (66), which can be written as which is the Bessel differential equation for the function when and are fixed to which in turn means that transformations (64) and (67) are Hence, the solution for (63) is of the form with where is the ordinary Bessel function with imaginary order. For the particular case when the factor ordering is zero, we can easily construct a wave packet [41, 45, 46] using the identity: so, the total wave function becomes Notice that the influence of extra dimensions through the presence of the moduli and appears in the solution in the amplitude of the wave function. We will comment on this later on.

(2) Case with null cosmological constant and . For this case we havewhose solution is So, the total wave function becomes

(3) If we include the cosmological constant term for this particular case, we have [44] where in order to have ordinary Bessel functions as solutions; in other case, we will have the modified Bessel function. When the factor ordering parameter equals zero, we have the same generic Bessel functions as solutions, having the imaginary order .

(4) and and any factor ordering :with the solutionwhere is a generic Bessel function. When , we have ordinary Bessel functions; in other case, we have modified Bessel functions.

(5) , , and factor ordering with the solution where And are Whittaker functions and are integration constants.

6. Final Remarks

In this work we have explored a compactification of a ten-dimensional gravity theory coupled with a time-dependent dilaton into a time-dependent six-dimensional torus. The effective theory which emerges through this process resembles the Einstein frame to that described by the Bianchi I model. By incorporating the barotropic matter and cosmological content and by using the analytical procedure of Hamilton equation of classical mechanics, in appropriate coordinates, we found the classical solution for the anisotropic Bianchi type I cosmological models. In particular, the Bianchi type I is completely solved without using a particular gauge. With these solutions we can validate our qualitative analysis on isotropization of the cosmological model, implying that the volume becomes larger in the corresponding time evolution.

We find that, for all cases, the Universe expansion is gathered as time runs while the internal space shrinks. Qualitatively this model shows us that extra dimensions are forced to decrease its volume for an expanding Universe. Also we notice that the presence of extra dimensions affects how fast the Universe (with matter) expands through the presence of a constant related to the moduli momenta. This is not unexpected since we are not considering a potential for the moduli, which implies that they are not stabilized and consequently an effective model should only take into account their constant momenta. We observe that isotropization is not affected in the cases without matter, but in the matter presence, isotropization can be favored or retarded according to how fast the moduli evolve with respect to each other.

It could be interesting to study other types of matter in this context, beyond the barotropic matter. For instance, the Chaplygin gas, with a proper time, characteristic to this matter, leads to the presence of singularities types I, II, III, and IV (generalizations to these models are presented in [4749]) which also appear in the phantom scenario to dark/energy matter. In our case, since the matter we are considering is barotropic, initial singularities of these types do not emerge from our analysis, implying also that phantom fields are absent. It is important to remark that this model is a very simplified one in the sense that we do not consider the presence of moduli-dependent matter and we do not analyze under which conditions inflation is present or how it starts. We plan to study this important task in a different work.

Concerning the quantum scheme we can observe that this anisotropic model is completely integrable without employing numerical methods, similar solutions to partial differential equation into the gravitational variables have been found in [50], and we obtain that the solutions in the moduli fields are the same for all Bianchi Class A cosmological models, because the Hamiltonian operator in (57) can be written in separated way as , where y represents the Hamiltonian to gravitational sector and the moduli fields, respectively, with the full wave function given by . In order to have the best candidates for quantum solutions become those that have a damping behavior with respect to the scale factor, represented in our model with parameter, in this way we will drop in the full solution the modified Bessel function or Bessel function , with being the order of these functions.

We can observe that the quantum solution in the sector is similar to the corresponding FRW cosmological model, found in different schemes [12, 22, 23, 32, 43]. Also, similar analysis based on a Bianchi type II model can be found in recent published paper by two authors of this work [51].

The presence of extra dimensions could have a stronger influence on the isotropization process by having a moduli-dependent potential, which can be gathered by turning on extra fields in the internal space, called fluxes. It will be interesting to consider a more complete compactification process in which all moduli are considered as time-dependent fields as well as time-dependent fluxes. We leave these important analyses for future work.

Appendix

Dimensional Reduction

With the purpose to be consistent, here we present the main ideas to dimensionally reduce action (1). By the use of the conformal transformation action (1) can be written aswhere the ten-dimensional scalar curvature transforms according to the conformal transformation asBy substituting expression (A.3) in (A.2) we obtain

The last expression is the ten-dimensional action in the Einstein frame. Expressing the metric determinant in four-dimensions in terms of the moduli field we have

By substituting the last expression (A.5) in (1) and considering thatwe obtain thatLet us redefine in the last expression the dilaton field aswhere . So, expression (A.7) can be written asThe four-dimensional metric means that the metric is in the string frame, and we should take a conformal transformation linking the String and Einstein frames. We label by the metric of the external space in the Einstein frame; this conformal transformation is given bywhich after some algebra gives the four-dimensional scalar curvature:where the function is given by the transformation:Now, we must replace expressions (A.10), (A.11), and (A.12) in expression (A.9) and we findAt first glance, it is important to clarify one point related to the stress-energy tensor which has the matrix form (6); this tensor belongs to the String frame. In order to write the stress-energy tensor in the Einstein frame we need to work with the last integrand of expression (1). So, after taking the variation with respect to the ten-dimensional metric and opening the expression we see that where we can observe that the four-dimensional stress-energy tensor in the Einstein frame is defined as we said in expression (7).

Competing Interests

The authors declare that they have no competing interests.

Acknowledgments

This work was partially supported by CONACYT 167335, 179881 Grants and PROMEP Grants UGTO-CA-3 and DAIP-UG 640/2015. This work is part of the collaboration within the Instituto Avanzado de Cosmología and Red PROMEP: Gravitation and Mathematical Physics under project Quantum Aspects of Gravity in Cosmological Models, Phenomenology and Geometry of Spacetime. One of authors (L. Toledo Sesma) was supported by a Ph.D. scholarship in the graduate program by CONACYT.