Galaxy-galaxy weak gravitational lensing in $f(R)$ gravity

TL;DR

This paper investigates galaxy-galaxy weak lensing in $f(R)$ gravity using simulated data, finding that GGL signals are only mildly affected compared to standard cosmology, and explores how combined analyses can probe matter fluctuations.

Contribution

It provides a detailed analysis of GGL in $f(R)$ gravity with mock catalogues, demonstrating the potential of joint GGL and galaxy clustering studies to test modified gravity models.

Findings

GGL enhancement is less than 5% at large scales in $f(R)$ gravity.

Galaxy-matter cross correlation coefficient remains near unity in $f(R)$ gravity.

Joint GGL and galaxy clustering analysis can effectively probe matter density fluctuations.

Abstract

We present an analysis of galaxy-galaxy weak gravitational lensing (GGL) in chameleon $f(R)$ gravity - a leading candidate of non-standard gravity models. For the analysis we have created mock galaxy catalogues based on dark matter haloes from two sets of numerical simulations, using a halo occupation distribution (HOD) prescription which allows a redshift dependence of galaxy number density. To make a fairer comparison between the $f(R)$ and $\Lambda$CDM models, their HOD parameters are tuned so that the galaxy two-point correlation functions in real space (and therefore the projected two-point correlation functions) match. While the $f(R)$ model predicts an enhancement of the convergence power spectrum by up to $\sim30\%$ compared to the standard $\Lambda$CDM model with the same parameters, the maximum enhancement of GGL is only half as large and less than 5\% on separations above $\sim1$-$2h^{-1}$Mpc, because the latter is a cross correlation of shear (or matter, which is more strongly affected by modified gravity) and galaxy (which is weakly affected given the good match between galaxy auto correlations in the two models) fields. We also study the possibility of reconstructing the matter power spectrum by combination of GGL and galaxy clustering in $f(R)$ gravity. We find that the galaxy-matter cross correlation coefficient remains at unity down to $\sim2$-$3h^{-1}$Mpc at relevant redshifts even in $f(R)$ gravity, indicating joint analysis of GGL and galaxy clustering can be a powerful probe of matter density fluctuations in chameleon gravity. The scale dependence of the model differences in their predictions of GGL can potentially allow to break the degeneracy between $f(R)$ gravity and other cosmological parameters such as $\Omega_m$ and $\sigma_8$.