Determining Cosmological-model-independent H0 with Gravitationally Lensed Supernova Refsdal

Abstract

The reappearance of supernova Refsdal with detailed modeling of the lens cluster allows us to measure the time-delay distance, which serves as a powerful tool to determine the Hubble constant (H0). We give a cosmological-model-independent method to estimate H0 through Gaussian process regression, using time-delay measurements from this lensed supernova in combination with supernova data from the Pantheon+ sample. Using eight mass models for the lens cluster, we infer H0 = 64.2+4.4-4.3 \, km\,s-1\,Mpc-1 and using two cluster models most consistent with the observations, we infer H0 = 66.3+3.8-3.6 \, km\,s-1\,Mpc-1. Our estimates of the value of H0 are in 1σ agreement with the results assuming a flat model and the uncertainties are comparable. Our constraint results on H0 from the eight lens models and the two lens models indicate 2σ and 1.8σ tensions with that estimated by Supernova H0 for the Equation of State, respectively. However, our median values of H0 from the two sets of lens models show good consistency with H0 inferred from Planck cosmic microwave background observations assuming model within 1σ. We also find that our results for H0 indicate 2σ deviations and 1.7σ deviations from the constraint results of H0 using six time-delay quasars by H0LiCOW with the same analysis method.