The effective theory of the Anton-Schmidt cosmic fluid within the Debye approximation is investigated. In this picture, the Universe is modeled out by means of a medium without cosmological constant. In particular, the Anton-Schmidt representation of matter describes the pressure of crystalline solids under deformations imposed by isotropic stresses. The approach scheme is related to the fact that the Universe deforms under the action of the cosmic expansion itself. Thus, we frame the dark energy term as a function of scalar fields and obtain the corresponding dark energy potential V(φ). Different epochs of the Universe evolution are investigated in terms of the evolution of φ. We show how the Anton-Schmidt equation of state is capable of describing both late and early epochs of cosmic evolution. Finally, numerical bounds on the Anton-Schmidt model with n = −1 are derived through a Markov Chain Monte Carlo analysis on the combination of data coming from type Ia Supernovae, observations of Hubble parameter, and baryon acoustic oscillations. Statistical comparison with the ΛCDM model is performed by the Akaike information criterion and Bayesian information criterion selection criteria. Results are in excellent agreement with the low-redshift data. A further generalization of the model is presented to satisfy the theoretical predictions at early-stage cosmology.

Effective field description of the Anton-Schmidt cosmic fluid

Giambò, Roberto;
2019-01-01

Abstract

The effective theory of the Anton-Schmidt cosmic fluid within the Debye approximation is investigated. In this picture, the Universe is modeled out by means of a medium without cosmological constant. In particular, the Anton-Schmidt representation of matter describes the pressure of crystalline solids under deformations imposed by isotropic stresses. The approach scheme is related to the fact that the Universe deforms under the action of the cosmic expansion itself. Thus, we frame the dark energy term as a function of scalar fields and obtain the corresponding dark energy potential V(φ). Different epochs of the Universe evolution are investigated in terms of the evolution of φ. We show how the Anton-Schmidt equation of state is capable of describing both late and early epochs of cosmic evolution. Finally, numerical bounds on the Anton-Schmidt model with n = −1 are derived through a Markov Chain Monte Carlo analysis on the combination of data coming from type Ia Supernovae, observations of Hubble parameter, and baryon acoustic oscillations. Statistical comparison with the ΛCDM model is performed by the Akaike information criterion and Bayesian information criterion selection criteria. Results are in excellent agreement with the low-redshift data. A further generalization of the model is presented to satisfy the theoretical predictions at early-stage cosmology.
2019
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11581/423580
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