Using spatial curvature with HII galaxies and cosmic chronometers to explore the tension in H0

Abstract

We present a model-independent measurement of spatial curvature k in the Friedmann-Lema\itre-Robertson-Walker (FLRW) universe, based on observations of the Hubble parameter H(z) using cosmic chronometers, and a Gaussian Process (GP) reconstruction of the HII galaxy Hubble diagram. We show that the imposition of spatial flatness (i.e., k=0) easily distinguishes between the Hubble constant measured with Planck and that based on the local distance ladder. We find an optimized curvature parameter k = -0.120+0.168-0.147 when using the former (i.e., H0=67.660.42 \, km\,s-1 \,Mpc-1), and k = -0.298+0.122-0.088 for the latter (H0=73.24 1.74 \,km\,s-1 \,Mpc-1). The quoted uncertainties are extracted by Monte Carlo sampling, taking into consideration the covariances between the function and its derivative reconstructed by GP. These data therefore reveal that the condition of spatial flatness favours the Planck measurement, while ruling out the locally inferred Hubble constant as a true measure of the large-scale cosmic expansion rate at a confidence level of 3σ.