Determining H0 from distance sum rule combining gamma-ray bursts with observational Hubble data and strong gravitational lensing

Abstract

Model-independent bounds on the Hubble constant H0 are important to shed light on cosmological tensions. We work out a model-independent analysis based on the sum rule, which is applied to late- and early-time data catalogs to determine H0. Through the model-independent B\'ezier interpolation of the observational Hubble data (OHD) and assuming a flat universe, we reconstruct the dimensionless distances of the sum rule and apply them to strong lensing data to derive constraints on H0. Next, we extend this method to the high-redshift domain including, in other two separated analyses, gamma-ray burst (GRB) data sets from the well-established Amati and Combo correlations. In all three analyses, our findings agree at 1σ level with the H0 determined from type Ia supernovae (SNe Ia), and only at 2σ level with the measurement derived from the cosmic microwave background (CMB) radiation. Our method evidences that the bounds on H0 are significantly affected by strong lensing data, which favor the local measurement from SNe Ia. Including GRBs causes only a negligible decrease in the value of H0. This may indicate that GRBs can be used to trace the expansion history and, in conjunction with CMB measurements, may heal the Hubble tension and accommodate to the flat paradigm purported by CMB data.

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