A new magnitude--redshift relation based on Type Ia supernovae

Abstract

We present a new empirical relation between the standardized magnitude (m) of Type Ia supernovae (SNe Ia) and redshift (z). Using Pantheon+ and DES-SN5YR, we find a negative linear correlation between m-5(z(1+z)) and z, implying that their magnitude--redshift relation can be parametrized with just two parameters: an intercept M and a slope b. This relation corresponds to the luminosity distance dL(z)=c\,H0-1z(1+z)10bz/5 and is valid up to at least z1.1. It outperforms the and flat wCDM models and the (2,1) Pad\'e approximant for dL(z), and performs comparably to the flat model and the (2,1) Pad\'e(j0=1) model of Hu et al. Furthermore, the relation is stable in the absence of low-z SNe, making it suitable for fitting Hubble diagrams of SNe Ia without the need to add a low-z sample. In deep fields in particular, assuming that the large-scale density is independent of the comoving radial coordinate, b q0+1. We fit the empirical relation to SN data in eight deep-field regions and find that their fitted M and b parameters are consistent within 1.6\,σ, in agreement with isotropy. The inferred q0 values, ranging from -0.6 to -0.4, are consistent within 1.5\,σ and significantly lower than zero, indicating statistically consistent cosmic acceleration across all eight regions. We apply the empirical relation to the DES-Dovekie and Amalgame SN samples, finding b values consistent with those from DES-SN5YR and Pantheon+. Finally, using the empirical relation in the hemispheric comparison method applied to Pantheon+ up to z=1.1, we find no evidence for anisotropies in M and b.