Phantom-Divide Crossing in Exponentially Coupled Quintessence and the Role of Neutrino-Mass Freedom

Abstract

We investigate a quintessence dark-energy model with an exponential potential and an exponential coupling to cold dark matter (CDM), hereafter referred to as the CQ-EXP model, using Planck CMB, DESI BAO, and DES-Dovekie supernova observations. We also examine how variations in the neutrino mass sector affect the constraints. When the neutrino mass sum is fixed at Σ mν=0.06 eV, the data favor a coupling between quintessence and CDM, with the coupling parameter β deviating from zero at more than 3σ. In particular, the observations favor the β<0 branch, where the energy transfer between the two dark sectors changes sign and the effective equation of state (EoS) of dark energy crosses the phantom divide, w=-1. When the effective neutrino mass parameter Σ mν,eff is treated as a free parameter, the data show a preference for negative values of Σ mν,eff. This additional freedom weakens the preference for the coupling between quintessence and CDM and leads to nearly identical values of χ2 min for the CQ-EXP models with β>0 and β<0, corresponding respectively to models without and with phantom-divide crossing in the effective EoS. Both values are slightly larger than that obtained in the w0waCDM model, indicating that the CQ-EXP model cannot be statistically distinguished from the w0waCDM model with the data considered here. Therefore, when Σ mν is fixed, current observations favor the CQ-EXP model with phantom-divide crossing. In contrast, when negative values of Σ mν,eff are allowed, a CQ-EXP dark energy without crossing w=-1 can also provide an effective explanation of the latest observations.