Characterising the secondary maximum in the r-band for Type Ia Supernovae: Diagnostic for the ejecta mass

Abstract

An increase in the number of studied Type Ia supernovae (SNe~Ia) has demonstrated that this class of explosions has a greater diversity in its observables than was previously assumed. The reasons (e.g. the explosion mechanism, progenitor system) for such a diversity remain unknown. Here, we analyse a sample of r-band light curves of SNe~Ia, focusing on their behaviour 2-4 weeks after maximum light, i.e. the second maximum. We characterise the second maximum by its timing (tr2) and the integrated flux (Fr2). We find that tr2 correlates with the "colour-stretch" parameter sBV, which can be used as a proxy for 56Ni mass, and Fr2, correlates with the transparency timescale, t0. Using Fr2, for a sample of 199 SNe from the Palomar Transient Factory and intermediate Palomar Transient Factory, we evaluate a distribution on t0 for a sample of SNe~Ia found in an "untargeted" survey. Comparing this distribution to the predictions of t0 ranges from models we find that the largest overlap in t0 values between models and observations is for the sub-Chandrasekhar double detonation models. We also compare our relations between t0 and Fr2, with that from 1-D explosion models of GK18 and confirm that Fr2, can be used as a diagnostic of the total ejecta mass.