Probing departures from by late-time datasets

Abstract

Observational data play a pivotal role in identifying cosmological models that are both theoretically consistent and empirically viable. In this work, we investigate the level of preference for dynamical dark energy over a cosmological constant using current late-time observational datasets, including Cosmic Chronometers , Baryon Acoustic Oscillations from DESI DR2, and different Type Ia supernova catalogs (Pantheon+, DES-Dovekie, Union3). We analyze various dynamical dark energy models, including ωCDM, oωCDM, ω0ωaCDM, Logarithmic, Exponential, JBP, BA, and GEDE. In most cases, the o and oωCDM models favor an open Universe. For the oωCDM, the inclusion of DES-Dovekie or Union3 data together with CC and DESI DR2 favors a nearly flat geometry. Using the CC + DESI DR2 dataset, the preference for dynamical dark energy lies between the 1-2σ level. When different supernova catalogs (DES-Dovekie or Union3) are included, the deviation from in the ωCDM, ω0ωaCDM, Logarithmic, JBP, BA, and GEDE models increases to the 2-2.74σ level, while the Pantheon+ sample yields deviations below the 2σ level. We find consistent evidence for ω0 > -1 and ωa < 0 across all dark energy models, indicating a preference for dynamical dark energy characterized by a Quintom-B type scenario. The paradigm has long served as the standard framework of modern cosmology; however recent DESI DR2 results have exposed emerging tensions with the cosmological constant , hinting at possible new physics in the dark energy sector. Even so, the currently available data are still not strong enough to definitively rule out the model.

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