Exploring non-Poisson satellite occupation in HOD models and its impact on 2- and 3-point galaxy clustering

Abstract

Understanding the connection between galaxies and dark matter halos is a central challenge in modern cosmology. The Halo Occupation Distribution (HOD) framework provides a widely used statistical description of how galaxies populate dark matter halos, enabling precise modelling of galaxy clustering. A common assumption in standard HOD models is that the number of satellite galaxies follows a Poisson distribution at fixed halo mass. In this work, we revisit this assumption and introduce the Conway-Maxwell-Poisson (CMP) distribution as a minimal extension of of the Poisson model, which add a single parameter, ν, to explore sub- and super-Poisson behaviour. We derive analytical approximations for the CMP expectation parameter λ and develop a numerical scheme that smoothly connects small- and large-λ regimes, achieving 5\% accuracy for 0.5 < ν< 2. Using the HODDIES package, we study the impact of non-Poisson satellite occupations on mock galaxy catalogues and clustering statistics. Variations in the variance of the satellite occupation significantly affect small-scale clustering, producing deviations of up to 10\% in projected clustering and 5\% in the monopole and quadrupole. We further investigate higher-order statistics using counts-in-cylinders (CiC) and the tree-level galaxy bispectrum. CiC statistics are highly sensitive to changes in the variance, with variations up to 30\%, while the tree-level galaxy bispectrum (in the Sugiyama basis) is only weakly affected (<2\% up to kmax = 0.3). These results suggest that non-Poisson satellite statistics are important for small-scale analyses, but should have a limited impact on cosmological constraints from power spectrum and bispectrum measurements using large scales kmax < 0.3.