Testing dissipative dark matter in causal thermodynamics
Abstract
In this paper we study the consistency of a cosmological model representing a universe filled with a one-component dissipative dark matter fluid, in the framework of the causal Israel-Stewart theory, where a general expression arising from perturbation analysis for the relaxation time is used. This model is described by an exact analytic solution recently found in [N. Cruz, E. Gonz\'alez and G. Palma, Gen. Rel. Grav. \textbf{52}, 62 (2020), which depends on several model parameters as well as integration constants, allowing the use of Type Ia Supernovae and Observational Hubble data to perform an astringent observational test. The constraint regions found for the parameters of the solution allow the existence of an accelerated expansion of the universe at late times, after the domination era of the viscous pressure, which holds without the need of including a cosmological constant. Nevertheless, the fitted parameter values lead to drawbacks as a very large non-adiabatic contribution to the speed of sound, and some inconsistencies, not totally conclusive, with the description of the dissipative dark matter as a fluid, which is nevertheless a common feature of these kind of models.
Cite
@article{arxiv.1906.04570,
title = {Testing dissipative dark matter in causal thermodynamics},
author = {Norman Cruz and Esteban González and Guillermo Palma},
journal= {arXiv preprint arXiv:1906.04570},
year = {2020}
}
Comments
11 pages, 3 figures, 2 Tables. Second Revised version, including new references, new SNe Ia data sample + the Observational Hubble data and slightly modified concluding remarks. Note: For the sake of completeness, the essential equations and basic descriptions to set the Israel-Stewart framework are quoted from our slightly older reference arXiv:1812.05009