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.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.