Constraints of Cosmic Expansion Using an MSF

TL;DR

This paper introduces a modified scale factor model that explains the universe's accelerating expansion without dark energy, fitting observational data well and offering a unified matter-dark energy framework.

Contribution

The paper proposes a novel modified scale factor model that accounts for cosmic acceleration without dark energy, validated against multiple observational datasets.

Findings

MSF model fits observational data comparably to $\\Lambda$CDM.

Best-fit parameters vary across datasets but show consistent acceleration.

Model demonstrates good compatibility with current astronomical observations.

Abstract

In this paper, we propose a modified scale factor (MSF) that allows us to explore the accelerating expansion of the universe without invoking the traditional dark-energy model, as described in the Lambda cold dark matter ($\Lambda$CDM) model. Instead, the MSF model introduces parameters that encapsulate the effects traditionally attributed to dark energy. To test the viability of this MSF, we constrained the model using the observational Hubble parameter (OHD), distance modulus measurements (SNIa), and their combined datasets (OHD + SNIa). We implement a Monte Carlo Markov Chain (MCMC) simulation to find the best-fit values of the model parameters. The MSF model produced best-fit values for the parameter $p$ associated with the power law of the matter-dominated era and $\beta$, the exponential parameter for the darkenergy-dominated era. For our MSF, these values are $p$ = 0.28 and $\beta$ = 0.52 when using SNIa data, $p$ = 0.63 and $\beta$ = 0.30 for OHD data and $p$ = 0.45 and $\beta$ = 0.53 for a combination of datasets (OHD + SNIa). The numerical results and plots of the deceleration parameter, fractional energy density, Hubble parameter, and luminosity distance are presented which are the key parameters for studying the accelerated expansion of the universe. We compare the results of our model with that of the $\Lambda$CDM model and reconcile them with astronomical observational data. Our results indicate that the MSF model shows promise, demonstrating good compatibility with current astronomical observations and performing comparably to the $\Lambda$CDM model across various datasets, particularly in predicting the accelerating expansion of the universe, while providing a unified framework that incorporates the simultaneous influence of matter and dark energy components.