Is the Model in Crisis?

Abstract

We present strong evidence for dynamical dark energy that challenges the standard model. Several dark energy scenarios are explored, including ω0ωaCDM, logarithmic, exponential, JBP, and BA parameterizations, along with non-flat cosmologies allowing for spatial curvature (k ≠ 0). Our analysis supports a flat Universe with k ≈ 0. Using MCMC techniques, we constrain these models with observational data from DESI~DR2 baryon acoustic oscillations, Type~Ia supernovae, and compressed CMB likelihoods. The results provide strong statistical evidence that ω ≠ -1, favoring dynamical dark-energy behavior consistent with a Quintom-B scenario (ω0 > -1, ωa < 0, and ω0 + ωa < -1). We also derive upper bounds on the total neutrino mass, Σ m, using CMB + DESI~DR2 data: Σ m < 0.066~eV for and Σ m < 0.075~eV for ωCDM. In the non-flat extensions, o and oωCDM, the limits relax to Σ m < 0.263~eV and Σ m < 0.520~eV, respectively. For the other models ω0ωaCDM, logarithmic, exponential, JBP, BA, and GEDE the constraints range between <0.043 and <0.127~eV. The effective number of relativistic species remains consistent with the standard value, Neff = 3.044, across all models. Bayesian evidence further shows that combining DES-SN5Y or Union3 supernova samples with CMB + DESI~DR2 produces measurable deviations from . Although no model reaches the 5σ significance threshold, several exhibit tensions exceeding 3σ, suggesting emerging cracks in the cosmological constant paradigm.