A Dynamical Scalar Field Model for Dark Energy: Addressing the Hubble Tension and Cosmic Evolution

Abstract

We propose a dynamical dark energy model based on a canonical scalar field with a hybrid potential of the form V(φ) = V0e-λφ + V1φn. We constrain the model's 11-dimensional parameter space using a comprehensive combination of cosmological data, including the Planck 2018 Cosmic Microwave Background (CMB) power spectra, Baryon Acoustic Oscillations (BAO), the Pantheon+ supernova sample, SH0ES and the matter power spectrum from SDSS. The model provides an excellent fit to the data, with a reduced chi-squared of 2red = 0.989, while successfully alleviating the Hubble constant tension. Our analysis yields a Hubble constant of H0 ≈ 72.820 km/s/Mpc, reducing the discrepancy between early and late-universe measurements. We find that the data favors a 'thawing' quintessence scenario, characterized by a potential slope parameter λ ≈ 0.056. This small but non-zero slope drives a late-time deviation from (w(z=0) ≈ -0.85) while preserving the standard expansion history at high redshifts. A model comparison using the Bayesian Information Criterion finds that the standard model is still slightly preferred ( = 2.178) due to its fewer parameters. Nevertheless, our results demonstrate that this hybrid potential model is a compelling, physically motivated alternative to a cosmological constant.

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