Cosmological Dynamics of Matter Creation with Modified Chaplygin Gas and Bulk Viscosity

Abstract

This work presents a comprehensive investigation of a novel cosmological model that unifies the Modified Chaplygin Gas (MCG) equation of state with gravitationally induced matter creation and bulk viscous dissipation in a spatially flat Friedmann-Lemaitre-Robertson-Walker spacetime. The MCG fluid is characterized by an exotic equation of state p = A - C/α, while the matter creation rate is taken as = 3β H and the bulk viscous pressure as π = -3H0 m1/2. We derive the modified Friedmann equations and obtain an analytical expression for the Hubble parameter H(z), which is then used to reconstruct the evolutionary trajectories of key cosmological parameters: the deceleration parameter q(z), jerk parameter j(z), and snap parameter s(z). The model parameters are constrained using two observational datasets: DS1 (Pantheon+ + Cosmic Chronometers + DESI BAO + σ8) and DS2 (DS1 + R22), employing a Markov Chain Monte Carlo (MCMC) analysis. The results indicate that the proposed hybrid model successfully generates a transition from decelerated to accelerated expansion, consistent with current observations. Notably, the inclusion of R22 data leads to a higher best-fit value of H0, helping to alleviate the H0 tension. Furthermore, we perform a rigorous thermodynamic analysis of the model by testing the Generalized Second Law (GSL) of thermodynamics. We compute the total entropy rate of change Stotal = Sfluid + Shorizon, finding it positive throughout cosmic history for both datasets, confirming the model's thermodynamic viability. The second derivative Stotal exhibits a clear transition from positive to negative values around z 1, indicating a shift from accelerating to decelerating entropy production a signature of late-time thermodynamic stabilization.