Impact of the SNe Ia Magnitude Transition at 20 Mpc on Cosmological Parameter Estimation

Abstract

We investigate the impact of a late-time transition in the standardized absolute magnitude M on the best-fit values of cosmological parameters using the Pantheon+ dataset. Extending previous analyses which focused on flat , we examine this transition within flat , wCDM, and CPL cosmologies, as well as a model-independent cosmographic expansion, employing both frequentist (2 minimization with AIC/BIC) and Bayesian (MCMC and Nested Sampling) inference frameworks. We confirm that the data consistently favor a step in absolute magnitude of M 0.19~mag at a characteristic distance of dcrit ≈ 20~Mpc. The inclusion of this transition leads to a statistically significant improvement in the quality of fit and has a distinct impact on parameter estimation: it induces a systematic increase in the inferred Hubble constant of approximately 2\% across all tested models. In contrast, we find that the dynamical parameters governing the background expansion, including the matter density m and the dark energy equation of state (w0, wa), remain stable and largely unaffected. These results indicate that the 20~Mpc feature acts primarily as a low-redshift calibration shift rather than a modification of the late-time expansion history.