Lightcurve Modelling of 2,205 ZTF DR2 Type~Ia Supernovae: Implications for SN Ia Physics and Cosmology

Abstract

We fit the multi-band light curves of 2,205 Type Ia supernovae (SNe~Ia) from the Zwicky Transient Facility DR2 with a one-zone radioactive decay model with a phenomenological addition to include Fe recombination physics. We find a strong correlation between inferred nickel mass and SALT2 stretch, which within our simplified modelling is linked to larger ejecta masses providing longer diffusion times, providing a physical basis for the brighter-slower relation. SN~Ia in low-mass hosts (10(M*/M) < 10) produce 12\% more 56Ni than those in high-mass hosts ( M Ni = 0.13~M), linking the host-galaxy mass step to ejecta properties and hinting at metallicity or age-dependent burning efficiencies. This suggests that standardisation based on physical parameters may remove the mass-step. SN~1991T-like events show higher ejecta masses (median 1.64~M vs. 1.38~M for normals) and produce 30\% more 56Ni, with 84\% having super-Chandrasekhar masses. Through Hierarchical modelling of 902 SNe (z ≤ 0.06), we find thermonuclear supernovae can be well described by a Gaussian distribution in ejecta mass and nickel mass with μ ej = 1.26 0.01~M (σ ej = 0.33 0.01~M) and μ Ni = 0.64 0.06~M (σ Ni = 0.42 0.02~M), respectively. This leads to inferred fractions of 43 2\% sub-M Ch (<1.2~M), 34 1\% near-M Ch (1.2--1.5~M), and 24 2\% super-M Ch (>1.5~M) events. This work provides a step towards holistic physical characterization of the local SN~Ia population, reinforcing the physical basis of SN~Ia standardization while quantifying diversity and environmental dependencies critical for understanding progenitor physics and mitigating systematics in precision cosmology.