Probing $f(R)$ cosmology with sterile neutrinos via measurements of scale-dependent growth rate of structure

TL;DR

This study constrains $f(R)$ gravity and sterile neutrino properties using cosmic observations, revealing parameter limits and degeneracies, and comparing results with the standard cosmological model.

Contribution

It provides new constraints on $f(R)$ gravity parameter $B_0$ and sterile neutrino mass using multiple cosmological datasets, accounting for scale-dependent growth rates.

Findings

Upper limit on $ ext{log}_{10}B_0$ is -4.1 at 95",

Sterile neutrino mass $<0.62$ eV (2$\sigma$) and $N_{ m eff}<3.90$ (2$\sigma$) in $f(R)$ model.

Abstract

In this paper, we constrain the dimensionless Compton wavelength parameter $B_0$ of $f(R)$ gravity as well as the mass of sterile neutrino by using the cosmic microwave background observations, the baryon acoustic oscillation surveys, and the linear growth rate measurements. Since both the $f(R)$ model and the sterile neutrino generally predict scale-dependent growth rates, we utilize the growth rate data measured in different wavenumber bins with the theoretical growth rate approximatively scale-independent in each bin. The employed growth rate data come from the peculiar velocity measurements at $z=0$ in five wavenumber bins, and the redshift space distortions measurements at $z=0.25$ and $z=0.37$ in one wavenumber bin. By constraining the $f(R)$ model alone, we get a tight 95\% upper limit of $\log_{10}B_0<-4.1$. This result is slightly weakened to $\log_{10}B_0<-3.8$ (at 2$\sigma$ level) once we simultaneously constrain the $f(R)$ model and the sterile neutrino mass, due to the degeneracy between the parameters of the two. For the massive sterile neutrino parameters, we get the effective sterile neutrino mass $m_{\nu,{\rm{sterile}}}^{\rm{eff}}<0.62$ eV (2$\sigma$) and the effective number of relativistic species $N_{\rm eff}<3.90$ (2$\sigma$) in the $f(R)$ model. As a comparison, we also obtain $m_{\nu,{\rm{sterile}}}^{\rm{eff}}<0.56$ eV (2$\sigma$) and $N_{\rm eff}<3.92$ (2$\sigma$) in the standard $\Lambda$CDM model.