Hierarchical clustering in chameleon $f(R)$ gravity

TL;DR

This study uses high-resolution N-body simulations to analyze how chameleon $f(R)$ gravity modifies higher-order clustering statistics and density distributions compared to General Relativity, revealing significant deviations especially at small scales and high redshifts.

Contribution

It provides the first detailed analysis of higher-order correlation functions and density PDFs in chameleon $f(R)$ gravity using state-of-the-art simulations, highlighting key deviations from GR.

Findings

Hierarchical scaling of reduced cumulants is preserved in $f(R)$ gravity.

Significant increases in $ar{\xi}_n$ and $S_n$ at small scales in $f(R)$ models.

Deviations from GR are most rapid at high and moderate redshifts.

Abstract

We use a suite of high resolution state-of-the-art N-body Dark Matter simulations of chameleon $f(R)$ gravity to study the higher order volume averaged correlation functions $\bar{\xi_n}$ together with the hierarchical $n$-th order correlation amplitudes $S_n=\bar{\xi}_n/\bar{\xi}_2^{n-1}$ and density distribution functions (PDF). We show that under the non-linear modifications of gravity the hierarchical scaling of the reduced cumulants is preserved. This is however characterised by significant changes of both the $\bar{\xi_n}$ and $S_n$'s values and their scale dependence with respect to General Relativity gravity (GR). In addition, we measure a significant increase of the non linear $\sigma_8$ parameter reaching $14, 5$ and 0.5% in excess of the GR value for the three flavours of our $f(R)$ models. We further note that the values of the reduced cumulants up to order $n=9$ are significantly increased in $f(R)$ gravity for all our models at small scales $R\simlt 30\hmpc$. In contrast the values of the hierarchical amplitudes, $S_n$'s, are smaller in $f(R)$ indicating that the modified gravity density distribution functions are deviating from the GR case. Furthermore we find that the redshift evolution of relative deviations of the $f(R)$ hierarchical correlation amplitudes is fastest at high and moderate redshifts $1\leq z \leq4$. The growth of these deviations significantly slows down in the low redshift universe. We also compute the PDFs and show that for scales below $\sim 20\hmpc$ they are significantly shifted in $f(R)$ gravity towards the low densities. Finally we discuss the implications of our theoretical predictions for measurements of the hierarchical clustering in galaxy redshifts surveys, including the important problems of the galaxy biasing and redshifts space distortions.