A Joint Analysis of Strong Lensing and Type Ia Supernovae to Determine the Hubble Constant

Abstract

We present a cosmological model-independent determination of the Hubble constant, H0, by combining time-delay measurements from seven TDCOSMO systems, Einstein radius measurements, and Type Ia Supernovae data sourced from the Pantheon+ sample. For each lens of time-delay system, we calculate the angular diameter distance DAl using the product DObs(zl) · DA, tObs(zl, zs), where DObs(zl) is reconstructed via Gaussian Processes from 99 Einstein radius measurements, and DA, tObs(zl,zs) is the time-delay angular distance. We also reconstruct the unanchored luminosity distance H0 DL(zl) from supernova data. By using the cosmic distance duality relation validity, we anchor DAl and H0 DL(zl) to infer H0 = 70.55 7.44 km/s/Mpc (68\% CL). Our result, though not resolving the Hubble tension, offers a cosmological model-independent consistency check and highlights the potential of using strong lensing and supernovae data via the cosmic distance duality relation to constrain H0.