Skewness as a Probe of Gravity: Real and Redshift Space Counts-In-Cells

Abstract

We study the counts-in-cells reduced skewness s3 for dark matter, halo, and galaxy distributions in both real and redshift space, using the ELEPHANT (Extended LEnsing PHysics with ANalytical ray Tracing) suite of N-body simulations. We compare General Relativity (GR) with two extended (EG) gravity models: f(R) gravity with chameleon screening and the normal-branch Dvali-Gabadadze-Porrati (nDGP) model with Vainshtein screening. We quantify the suppression of s3 by redshift-space distortions (RSD), finding that while small-scale skewness is strongly reduced, the F5 model retains a 4\% deviation from GR in galaxy samples, corresponding to a 2σ significance. We show that the ratio s3RSD/s3real is approximately independent of the gravity model across tracers and redshifts. Our results demonstrate that real-space predictions can help reliably infer redshift-space skewness in both GR and extended gravity, providing a new tool for testing gravity with current and forthcoming galaxy redshift surveys.