Testing the Constancy of Type Ia Supernova Luminosities with Gaussian Process

Abstract

Type Ia supernovae (SNe~Ia) are central to studies of cosmic expansion, under the assumption that their absolute magnitude MB does not evolve with redshift. Even small drifts in brightness can bias cosmological parameters such as H0 and w. Here we test this assumption using a non-parametric Gaussian Process (GP) reconstruction of the expansion history from cosmic chronometer H(z) data, which provides a model-independent baseline distance modulus, μ GP(z). To propagate uncertainties, we draw Monte Carlo realizations of H(z) from the GP posterior and evaluate them on a Chebyshev grid, which improves numerical stability and quadrature accuracy. Supernova observations are then compared to this baseline through residuals, MB(z), and their derivatives. Applying this method to Pantheon+ (1701 SNe~Ia) and DES 5YR (435 SNe~Ia), we find that SNe~Ia are consistent with being standard candles within 1σ, though both datasets exhibit localized departures: near z 1 in Pantheon+ and at z 0.3--0.5 in DES. The presence of similar features in two independent surveys suggests they are not purely statistical. Our results point toward a possible non-monotonic luminosity evolution, likely reflecting different physical drivers at different epochs, and highlight the need for a deeper astrophysical understanding of SN~Ia populations.