Interaction of polytropic dark energy in cosmological model: Constraints from observational data

Abstract

We investigate an interacting polytropic dark energy (PDE) model characterised by the equation of state pd = α d\,1+1β, where the interaction between dark energy and pressureless matter is modelled via a linear coupling term Q = 3η Hd. The background dynamics are formulated by deriving the Hubble parameter in the interacting scenario, and the model parameters are constrained through a Markov Chain Monte Carlo (MCMC) analysis using three joint observational data sets: Hubble77+BAO26, Hubble77+Pantheon+, and Hubble77+BAO26+DESI DR2. The resulting best-fit values of (H0, d0, η) are (69.22+1.27-1.24,\,0.73+0.02-0.02,\,-0.22+0.10-0.12), (69.23+1.27-1.22,\,0.73+0.02-0.02,\,-0.34+0.15-0.17), and (67.77+1.26-1.24,\,0.73+0.02-0.02,\,\\-0.02+0.10-0.11) respectively for the respective data combinations. Our results indicate a positive energy density and negative pressure over the full redshift range, with the evolution of the equation-of-state parameter and state finder parameters placing the model firmly within the Quintessence regime. The study of the deceleration parameter also reveals a shift from a decelerating to an accelerating cosmic expansion. The estimated present age of the Universe is 14\,Gyr, consistent with recent observational data. Furthermore, the sign of Q implies a current energy transfer from dark energy to matter. These findings support the interacting PDE framework as a viable candidate for explaining late-time cosmic acceleration and related large-scale dynamics.