Leveraging SN Ia spectroscopic similarity to improve the measurement of H₀

Recent studies suggest spectroscopic differences explain a fraction of the variation in Type Ia supernova (SN Ia) luminosities after light-curve/color standardization. In this work, (i) we empirically characterize the variations of standardized SN Ia luminosities, and (ii) we use a spectroscopically inferred parameter, SIP, to improve the precision of SNe Ia along the distance ladder and the determination of the Hubble constant (H-0). First, we show that the Pantheon+ covariance model modestly overestimates the uncertainty of standardized magnitudes by similar to 7%, in the parameter space used by the SH0ES Team to measure H-0; accounting for this alone yields H-0=73.01 +/- 0.92 km s(-1) Mpc(-1). Furthermore, accounting for spectroscopic similarity between SNe Ia on the distance ladder reduces their relative scatter to similar to 0.12 mag per object (compared to similar to 0.14 mag previously). Combining these two findings in the model of SN covariance, we find an overall 14% reduction (to +/- 0.85km s(-1) Mpc(-1)) of the uncertainty in the Hubble constant and a modest increase in its value. Including a budget for systematic uncertainties itemized by Riess et al. (2022a), we report an updated local Hubble constant with similar to 1.2% uncertainty, H-0=73.29 +/- 0.90km s(-1) Mpc(-1). We conclude that spectroscopic differences among photometrically standardized SNe Ia do not explain the ``Hubble tension." Rather, accounting for such differences increases its significance, as the discrepancy against Lambda CDM calibrated by the Planck 2018 measurement rises to 5.7 sigma.