Testing $\gamma\delta$CDM Model in the Redshift Bins

TL;DR

This paper tests the redshift dependence of the Hubble constant within a new $b3b4$CDM model based on $f(R)$ gravity, finding it remains constant and fits observational data better than $b5$CDM.

Contribution

It introduces a novel $b3b4$CDM model based on $f(R)$ gravity and demonstrates its consistency with data, addressing the Hubble tension.

Findings

The Hubble constant does not evolve with redshift in the $b3b4$CDM model.

The model fits observational data better than $b5$CDM according to information criteria.

The Hubble constant value aligns with late Universe observations within 1$c3$.

Abstract

The Hubble crisis is the discrepancy in the values of the Hubble constant inferred from diverse observations in the late and early Universe, being of the order 5$\sigma$. Instead of resolution, the conflict is getting larger with further late-time observations. A fundamental constant should be and remain constant throughout the cosmological history and thus at all redshifts. The fact that it turns out to be a function of redshift in the $\Lambda$CDM model points out that either there is a problem with the current cosmological model, indicating unknown new physics, or there are unknown systematics in some of the observations. In this work, we investigate the redshift dependence of the Hubble constant in the $\gamma\delta$CDM cosmological model, which is a new cosmological model based on $f(R)$ gravity in an anisotropic background. Through data analysis with the Pantheon+ type Ia supernovae, the cosmic chronometers Hubble, and both the old and the Dark Energy Spectroscopic Instrument (DESI) baryon acoustic oscillation data, we establish that the Hubble constant in our model does not evolve with redshift. We also confirm that our model fits the aforementioned data better than the $\Lambda$CDM model by checking various information criteria. The value of the Hubble constant obtained in the $\gamma\delta$CDM model is in the 1$\sigma$ bound of the late Universe observations.