Addressing the Hubble Tension: Insights from Reversible and Irreversible Thermodynamic Processes

Abstract

We investigate reversible and irreversible thermodynamic processes in cosmology and their impact on the Hubble tension. Gravitationally induced adiabatic matter creation/annihilation is treated as irreversible, while energy exchange between the cosmic bulk and horizon is modeled as reversible. Two scenarios are proposed: Model I features matter creation/annihilation across all species with energy transfer to effective entropic dark energy; Model II considers dark matter creation/annihilation with energy flow from baryonic matter and radiation. The creation rate is parameterized as (t)=0 H, with energy transfer controlled by γ. We constrain both models using Pantheon+ supernovae, CMB distance priors, baryon acoustic oscillations, gamma-ray bursts, and cosmic chronometers, with and without SH0ES. When SH0ES is included, matter annihilation (0<0) is statistically preferred, yielding H0 = 71.75 0.79 km s-1 Mpc-1 (Model I) and H0 = 71.06 0.81 km s-1 Mpc-1 (Model II), corresponding to 1.2σ and 1.8σ consistency with the SH0ES value 73.17 0.86 km s-1 Mpc-1. Matter creation (0>0) or pure energy flow (=0) do not improve the tension. Without SH0ES, information criteria show no preference over . For the matter annihilation/creation with energy flow, the effective entropic dark energy evolves dynamically, mimicking radiation and matter before recombination and approaching a cosmological constant at late times. These results demonstrate that thermodynamically motivated interactions can alleviate the Hubble tension when calibrated with local measurements, while remaining consistent with cosmological data.