Late time transition of Universe and the hybrid scale factor

E Aydiner,T Dereli,M Sarisaman,I Basaran-Öz

doi:10.1140/epjc/s10052-022-09996-2

E Aydiner, T Dereli + Show 2 more

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https://doi.org/10.1140/epjc/s10052-022-09996-2

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Abstract

In this study, we propose an interacting model to explain the physical mechanism of the late time transition from matter-dominated era to the dark energy-dominated era of the Universe evolution and to obtain a scale factor a(t) representing two eras together. In the present model, we consider a minimal coupling of two scalar fields which correspond to the dark matter and dark energy interacting through a potential based on the FLRW framework. Analytical solution of this model leads to a new scale factor a(t) in the hybrid form a(t)=a_{0} (t/t_{0})^{alpha } e^{ht/t_{0}}. This peculiar result reveals that the scale factor behaving as a (t) propto (t/t_{0})^{alpha } in the range t/t_{0}le t_{c} corresponds to the matter-dominated era while a(t) propto exp (ht/t_{0}) in the range t/t_{0}>t_{c} accounts for the dark energy-dominated era, respectively. Surprisingly, we explore that the transition from the power-law to the exponential expansion appears at the crossover time t_{0} approx 9.8 Gyear. We attain that the presented model leads to precisely correct results so that the crossover time t_{0} and alpha are completely consistent with the exact solution of the FLRW and re-scaled Hubble parameter H_{0} lies within the observed limits given by Planck, CMB and SNIa data (or other combinations), which lead to consistent cosmological quantities such as the dimensionless Hubble parameter h, deceleration parameter q, jerk parameter j and EoS parameter w. We also discuss time dependent behavior of the dark energy and dark matter to show their roles on the time evolution of the universe. Additionally, we observe that all main results completely depend on the structure of the interaction potential when the parameter values are tuned to satisfy the zero energy condition. Finally, we conclude that interactions in the dark sector may play an important role on the time evolution and provides a mechanism to explain the late time transition of the Universe.

Highlights

Observations of Type Ia Supernova (SNIa) show that the expansion of Universe is accelerating faster than expected [1,2]
It has been suggested that dark energy (DE) which behaves like the opposite of gravity and has repulsive pressure is the source of this accelerated expansion of the universe and this phenomenon is called the late time transition of the universe evolution
We introduce a cosmology model to explain the physical mechanism of the transition from the matter-dominated to dark energy-dominated era and to find a hybrid scale factor that covers both periods

Summary

Introduction

Observations of Type Ia Supernova (SNIa) show that the expansion of Universe is accelerating faster than expected [1,2]. After observing that the universe is expanding at an accelerated rate, the existence of dark energy has been held responsible as the source of this expansion and many interesting DE models have been proposed in the literature such as quintessence [3], phantom [4], k-essence [5], tachyon [6], Chaplygin gas [7], holographic dark energy [8] These models are the leading candidates for explaining the physical origin of the dark energy, they are far from explaining the physical mechanism of the late time transition. The other point is rather distinct from the first one where the key question is: Can we describe this critical transition as a phase transition or a catastrophic transition? If we view the problem in terms of the statistical mechanics of phase transitions, we can not say that it is a first

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