Noncommutativity, Sáez–Ballester Theory and Kinetic Inflation
Abstract
:1. Introduction
2. A Noncommutative Cosmological Scenario in Sáez–Ballester Theory
3. Kinetic Inflation and the Horizon Problem
3.1. Commutative Case
3.2. Noncommutative Case
- In the early times, both the scalar field and the scale factor experience accelerated expansion.
- Thereafter, there is another different phase in which both of them decelerate, see Figure 1.
- At late times, both and asymptotically tend to zero.Up to now, we can conclude that stages 1 and 2 indicate that our NC model may be considered as a successful cosmological inflationary model (see also the discussions will be presented in the following). Concretely, an inflationary phase took place at the earlier times, and afterward, there is a radiation-dominated epoch. Moreover, the effects of the dynamical noncommutativity (12) provide an appropriate transition from the accelerating phase to the decelerating one, which is known as the graceful exit. However, stage (iii) may be interpreted as a quantum gravity footprint as the coarse-grained explanation.
- Let us now analyze the time behavior of the energy density and pressure, see, for instance, the upper right panel of Figure 2. It is seen that always takes positive values such that it increases during the inflationary epoch to reach its maximum value. Soon after exiting from the accelerated phase, it decreases forever. Whilst, both the and always take negative values. In contrast to the , they decrease during the inflationary phase whilst increasing during the radiation-dominated era. They reach their minimum value at the moment of the transition phase.
- In contrast to exact solutions, we should not always expect a numerical solution to satisfy the conservation equation identically. In this regard, it is worth plotting the quantity on the left-hand side of Equation (22) to find out how much disperses from zero (for this we use the numerical solution of Equation (25)). Therefore, for every set of the ICs and the values of the parameters, which have been used to depict the behavior of the quantities, we have checked its corresponding degree of accuracy. Specifically, for every numerical set, we have plotted the corresponding numerical error to be sure that they whether or not satisfy the conservation Equation (22), see, for instance, the lower panels of Figure 2.
- We have also investigated the time behavior of , , their first and second derivatives (with respect to the cosmic time) for different values of the parameters and n, see, for instance, Figure 3 and Figure 4, which show the behavior of and against the cosmic time. Our consequences indicate that, for a specific set of values, by changing the values of (or n) and leaving the others unchanged, there are no perceptible changes in the general behavior of the quantities, which was reported in stages 1 to 5. Notwithstanding, we found that for any t, assuming , the smaller the value of , the larger the values of a and . Moreover, our endeavors have shown that the smaller the value of , the shorter the amount of the interval time of the inflationary epoch. According to Figure 4, an interpretation can also be presented for the case if only n varies.
- Up to now, we have seen that our herein NC model can provide an accelerating phase at early times, and soon after the scale factor can gracefully exit from that accelerating phase and enter to a decelerating phase, which could be assigned to the radiation-dominated era. Therefore, it seems that our model, disregarding the 60 e-fold duration, can be considered as a proper inflationary scenario. Notwithstanding, it has been believed that among the problems associated with the standard cosmology, the horizon problem is the most important one, which should be resolved by a successful inflationary scenario. In this respect, let us investigate only a nominal condition as the key to resolving the horizon problem [40,41]:In order to check satisfaction of the nominal condition (28), we first should obtain . In this respect, for our herein NC, we substitute the relations associated with the scale factor from relations (24) into (29). Therefore, we obtain an integration over with an unknown integrand (as a function of the scalar field), which, in turn, is obtained from (25). Moreover, we should also substitute the Hubble parameter (which can be also obtained from ) from (23) into (28). Consequently, investigating the nominal condition (28) for our herein NC model is not possible unless we obtain from solving (25). However, as mentioned, for the NC case, we have to apply numerical analysis. Our numerical endeavors have shown that condition (28) is satisfied for every set of values that yield the above-mentioned stages 1 to 6, see, for instance, Figure 5.
4. Cosmological Dynamics in Deformed Phase Scenario
5. Conclusions
- In this work, we have investigated the effects of the noncommutativity for a particular case. More concretely, we have restricted our attention to a special case where (i) the ordinary matter and the scalar potential are absent; (ii) a particular dynamical deformation between only the conjugate momenta was proposed. Obviously, by removing either one or more of the above restrictions, one can construct more extended models, which may yield more interesting results. For instance, generalizing this work to an NC model including a non-vanishing scalar potential, but still admitting the other constraints, we can establish NC counterparts for the deformed versions of the Luccin–Mataresse model [43] and the Barrow–Burd–Lancaster–Madsen model [44,45,46], see also [46]. The generalized version of the former and of the latter has been established in the non-deformed phase space in the context of SB theory [47]. Such extended frameworks have been investigated and will be presented within our forthcoming works.
- In comparison with the NC model presented in [48], we observe that in our herein NC model, there are two extra free parameters, i.e., and n, by which one can not only provide different behaviors for the physical quantities but also it may assist to retrieve appropriate values for the e-fold number (which is also one of the essential features of an expected inflationary epoch) to be in agreement with the observational data. In a particular case where and , we recover the corresponding model investigated in [48]. Moreover, in another particular case where and , using transformation
- We should emphasize that it is almost impossible to retrieve the Lagrangian associated with our NC model, and therefore, it is a complicated procedure to investigate the quantum features of the model by means of the perturbation analysis. In this respect, at the level of the field equations, we have obtained a proper NC differential equation associated with the evolution of the scale factor. By means of such a procedure as well as by establishing the corresponding dynamical setting, one may probe the possible relations between the parameters appeared in our model (i.e., NC parameter, SB coupling parameter, n and the integration constants) and the quantum corrections observed in the Starobinsky inflationary model to find a feasible correspondence between these scenarios.
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
NC | noncommutative |
SB | Sáez–Ballester |
FLRW | Friedmann–Lemaître–Robertson–Walker |
1 | Some arguments for such a deformation have been presented in [30]. |
2 | In what follows, let us briefly present another approach to obtain the NC field equations, see, for instance, [37,38]. In order to obtain the Hamiltonian corresponding to the NC model, we proceed as follows. (i) All the variables of (4) should be replaced by new ones, for instance, primed variables. (ii) Introducing the only transformation , and assuming that the other primed variables are equal to the corresponding unprimed ones, we can easily recover not only the deformed Poisson bracket (12) but also the NC Hamiltonian. (iii) Finally, using the latter together with usual (standard) Poisson brackets, we can easily obtain the NC counterparts of (5)–(8). |
3 | In this work, let us skip the cosmological model corresponding to , see Section 5. |
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Rasouli, S.M.M. Noncommutativity, Sáez–Ballester Theory and Kinetic Inflation. Universe 2022, 8, 165. https://doi.org/10.3390/universe8030165
Rasouli SMM. Noncommutativity, Sáez–Ballester Theory and Kinetic Inflation. Universe. 2022; 8(3):165. https://doi.org/10.3390/universe8030165
Chicago/Turabian StyleRasouli, S. M. M. 2022. "Noncommutativity, Sáez–Ballester Theory and Kinetic Inflation" Universe 8, no. 3: 165. https://doi.org/10.3390/universe8030165
APA StyleRasouli, S. M. M. (2022). Noncommutativity, Sáez–Ballester Theory and Kinetic Inflation. Universe, 8(3), 165. https://doi.org/10.3390/universe8030165