📝 SummarXiv

Abstract

We present a scalar-field formulation of the generalized Chaplygin gas (GCG) and modified Chaplygin gas (MCG) models, in which the cosmic fluid dynamics are reproduced by canonical Lagrangians with analytically derived energy density $\rho(\phi)$, pressure $p(\phi)$, and scalar potential $V(\phi)$. This framework provides a unified description of dark matter and dark energy, transitioning naturally from a matter-dominated phase at early times to a negative-pressure dark-energy phase at late times. In this scalar-field formulation, the GCG and MCG models are naturally applicable to both theoretical analyses and numerical simulations. Extending this approach, we develop a systematic method to obtain a class of integrable scalar-field cosmological models. In this study, we use this method to construct a new scalar-field altered Chaplygin gas (ACG) model. To investigate the viability of Chaplygin-type models, we perform a likelihood analysis using the Pantheon+ Type Ia supernova compilation together with Cepheid-calibrated distances. We examine four models, $\Lambda$CDM, GCG, MCG, and ACG, obtaining posterior constraints on the Hubble constant $H_0$, the present-day effective equation of state $\omega_0$, the transition redshift $z^\star$, and the cosmic age $t_0$. With the Cepheid calibration fixing the absolute distance scale, the inferred $H_{0}$ remains nearly model-independent. The Chaplygin-type models predict an earlier onset of cosmic acceleration than $\Lambda$CDM and give a broader range for the inferred age of the Universe, reflecting their greater flexibility in late-time expansion histories. Among them, the ACG model provides tighter parameter constraints, while the GCG and MCG models produce broader posteriors due to parameter degeneracies.