Viscous Fluid Models of Cosmic Acceleration in FRW Spacetime Using MCMC Constraints
Abstract
This study combines theoretical advancements with observational limitations to investigate the cosmological implications of a bulk viscous modified Chaplygin gas (MCG) in a Friedmann--Robertson--Walker (FRW) in (3+1) dimensional spacetime framework. We provide analytical solutions for both viscous and non-viscous cases, pointing out variations in the energy density evolution, the Hubble parameter dynamics, and the deceleration parameter transitions. Bulk viscosity suppresses oscillations in structure creation, a well-known drawback of Chaplygin gas models in larger dimensions, as shown by a thorough perturbation analysis. Using the bulk viscosity coefficient and Hubble expansion parameter, which are incorporated by the total pressure and the appropriate pressure and by using energy momentum conservation law determined time time-dependent density. With the help of three conditions ( = 0, ≠0, and we neglect both bulk viscosity and presence of Chaplygin gas, i.e A=0 and =0) created three different models as the Hubble parameter is a function of redshift z. By applying the MCMC method to these models, we have gone through observational analysis by using the Hubble and BAO datasets.
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