Connecting the Light Curves of Type IIP Supernovae to the Properties of their Progenitors

Abstract

Observations of core-collapse supernovae (CCSNe) reveal a wealth of information about the dynamics of the supernova ejecta and its composition but reveal very little direct information about the progenitor star. Constraining properties of the progenitor and the explosion, such as explosion energy, requires coupling the observations with a theoretical model of the explosion. Here, we use a new model for driving turbulence-aided neutrino-driven core-collapse supernovae in 1D (STIR) which contains a non-parametric treatment of the neutrino transport while also accounting for turbulence and convection. We couple this with the SuperNova Explosion Code to produce bolometric light curves from a landscape of CCSNe driven from self-consistent CCSN simulations with robust neutrino transport. We compare our results to several well observed bolometric light curves of Type IIP CCSNe and find that our best fitting models differ from those found in previous studies using thermal bomb explosions, indicating ZAMS masses as much as about 10M$_{\odot}$ greater than previous studies. Using our large sample of 136 self-consistent CCSN explosions, we explore correlations between observable features of the light curves and properties of the progenitor star. Among other significant correlations, we find a robust linear relationship between light curve plateau luminosity and the iron core mass of the progenitor. This relationship allows for properties of the core of the progenitor to be constrained for the first time from photometry alone.