Revealing Limitation in the Standard Cosmological Model: A Redshift-Dependent Hubble Constant from Fast Radio Bursts

Abstract

A major issue in contemporary cosmology is the persistent discrepancy, known as the Hubble tension, between the Hubble constant (H0) estimates from local measurements and those inferred from early-Universe observations under the standard cold dark matter () paradigm. Recent advances have identified fast radio bursts (FRBs), a class of extragalactic phenomena observable at considerable redshifts, as a promising observational tool for probing late-time cosmology. In this study, we incorporate two complementary methodologies, machine learning algorithms and Bayesian analysis, on a set of localized FRBs to rigorously test the consistency of the model at late cosmic epochs. Our results reveal a statistically significant redshift-dependent variation of H0 when using separate priors on baryon density parameters b or bh2, indicating contradiction to the core postulate of . However, when the priors are combined, this redshift dependence disappears, yielding a consistent estimate of H0. We further validate that the redshift dependency of H0 can be removed within the more flexible framework of w0waCDM model even without combining the priors. These findings highlight that the redshift evolution of H0 is not merely an artifact of the standard model but an indication of a deeper inadequacy in the model, supporting the need for a more flexible cosmological framework.