Model-Independent Analysis of Type Ia Supernova Datasets and Implications for Dark Energy

Abstract

Recent analyses combining DESI DR2 BAO with CMB and SNe Ia data have reported 2.8--4.2σ evidence for dynamical dark energy, but the significance depends strongly on the supernova sample, raising the question of whether this signal reflects new physics, dataset-specific systematics, or the choice of dark energy parameterization. We investigate this question by analyzing four SNe Ia compilations (Pantheon, Pantheon+, DES-Dovekie, and Union3) with DESI DR2 BAO and Planck CMB distance priors, using flux averaging, model-independent expansion rate extraction, parametric (w0 waCDM) fits, and a non-parametric reconstruction of the dark energy density ratio X(z) DE(z)/ DE(0). Flux averaging reduces the m difference between SNe and DESI from 2σ to 1σ for Pantheon+ and DES-Dovekie. The reconstructed X(z) for DESI DR2 + CMB + SNe is consistent with for Pantheon, Pantheon+, and DES-Dovekie except at 0.5<z<1, consistent with Wang \& Freese (2026). The largest deviation occurs at z=2/3, reaching 2.7σ for Pantheon+ but only 1.6--1.7σ for Pantheon and DES-Dovekie. The X(z) for DESI DR2 + CMB + Union3 is consistent with these within 1σ, but shows an additional 2.4σ deviation at z=1/3 besides the 2.7σ deviation at z=2/3. Across all analyses, the departure from correlates with each dataset's m preference. We demonstrate that a pure universe with the measured m differences can reproduce the observed X(z) pattern, providing a viable alternative interpretation of the observed X(z) ≠ 1 pattern. Future surveys by Euclid and Roman with sub-percent m constraints will be essential to determine whether the signal reflects genuine dark energy evolution or residual inter-probe m inconsistencies.