Putting Flat $\Lambda$CDM In The (Redshift) Bin
Abstract
Flat CDM cosmology is specified by two constant fitting parameters at the background level in the late Universe, the Hubble constant and matter density (today) . Mathematically, and are either integration constants arising from solving ordinary differential equations or are directly related to integration constants. Seen in this context, if fits of the CDM model to cosmological probes at different redshifts lead to different parameters, this is a mismatch between mathematics and observation. Here, in mock observational Hubble data (OHD) (geometric probes of expansion history) we demonstrate evolution in distributions of best fit parameters with effective redshift. As a result, considerably different best fits from Planck-CDM cannot be precluded in high redshift bins. We explore if OHD, Type Ia supernovae and standardisable quasar samples exhibit redshift evolution of best fit CDM parameters. In all samples, we confirm a decreasing and increasing trend with increasing bin redshift. Through comparison with mocks, we confirm that similar behaviour can arise randomly within the flat CDM model with probabilities as low as (). We present complementary profile distribution analysis confirming the shifts in cosmological parameters in high redshift bins. In particular, we identify a redshift range where Planck values are disfavoured at () confidence level in a combination of OHD and supernovae data.
Cite
@article{arxiv.2206.11447,
title = {Putting Flat $\Lambda$CDM In The (Redshift) Bin},
author = {Eoin Ó Colgáin and M. M. Sheikh-Jabbari and Rance Solomon and Maria G. Dainotti and Dejan Stojkovic},
journal= {arXiv preprint arXiv:2206.11447},
year = {2024}
}
Comments
5 pages, 10 figures; v2 added explanations and appendix; v3 profile likelihood analysis added, to appear in Physics of the Dark Universe