Light and color curve properties of type Ia supernovae: Theory vs. Observations

Abstract

We study optical light curve(LC) relations of type Ia supernovae(SNe~Ia) for their use in cosmology using high-quality photometry published by the Carnegie-Supernovae-Project (CSP-I). We revisit the classical luminosity-decline-rate ( m15) relation and the Lira-relation, as well as investigate the time evolution of the (B-V) color and B(B-V), which serves as the basis of the color-stretch relation and Color-MAGnitude-Intercept-Calibrations(CMAGIC). Our analysis is based on explosion and radiation transport simulations for spherically-symmetric delayed-detonation models(DDT) producing normal-bright and subluminous SNe~Ia. Empirical LC-relations can be understood as having the same physical underpinnings: i.e. the opacities, ionization balances in the photosphere, and radioactive energy deposition changing with time from below to above the photosphere. Some 3-4 weeks past maximum, the photosphere recedes to 56Ni-rich layers of similar density structure, leading to a similar color evolution. An important secondary parameter is the central density c of the WD because at higher densities more electron capture elements are produced at the expense of 56Ni production. This results in a m15 spread of 0.1 mag for normal-bright and 0.7 mag in sub-luminous SNe~Ia and ≈0.2 mag in the Lira-relation. We show why color-magnitude diagrams emphasize the transition between physical regimes, and allow to construct templates depend mostly on m15 with little dispersion in both the CSP-I sample and our DDT-models. This allows to separate intrinsic SN~Ia variations from the interstellar reddening characterized by E(B-V) and RB. Mixing of different explosion scenarios causes a wide spread in empirical relations which may suggest one dominant scenario.