Updated observational constraints on ϕCDM dynamical dark energy cosmological models

Abstract

We present updated observational constraints on the spatially flat ϕCDM model, where dark energy is described by a minimally coupled scalar field ϕ with an inverse power-law potential V=V0 ϕ-α. Using Planck 2018 CMB temperature, polarization (P18), and lensing power spectra (lensing), along with a compilation of non-CMB data including baryon acoustic oscillation, type Ia supernova, Hubble parameter, and growth rate measurements, we constrain ϕCDM and ϕCDM+AL models where AL is the CMB lensing consistency parameter. The scalar field parameter α, which governs dark energy dynamics, is more tightly constrained by non-CMB data than by CMB data alone. For the full dataset, we obtain α= 0.055 0.041 in the ϕCDM model and α= 0.095 0.056 in the ϕCDM+AL model, mildly favoring evolving dark energy over a cosmological constant by 1.3σ and 1.7σ. The Hubble constant is H0=67.55-0.46+0.53 km s-1 Mpc-1 in the ϕCDM model, consistent with median statistics and some local determinations, but in tension with other local determinations. The constraints for matter density and clustering amplitude (Ωm = 0.3096 0.0055, σ8 = 0.8013-0.0067+0.0077) of the flat ϕCDM model statistically agree with ΛCDM model values. Allowing AL to vary reduces tensions between CMB and non-CMB data, although we find AL = 1.105 0.037, 2.8σ higher than unity, consistent with the excess smoothing seen in Planck data. Model comparison using AIC and DIC indicates that the ϕCDM model provides a fit comparable to ΛCDM, with the ϕCDM+AL slightly preferred. Overall, while the ΛCDM model remains an excellent fit, current data leave open the possibility of mildly evolving quintessence-like dynamical dark energy.