We introduce an emulator-based method to model the cross-correlation between cosmological voids and galaxies. This allows us to model the effect of cosmology on void finding and on the shape of the void-galaxy cross-correlation function, improving on previous template-based methods. We train a neural network using the AbacusSummit simulation suite and fit to data from the Sloan Digital Sky Survey Baryon Oscillation Spectroscopic Survey sample. We recover information on the growth of structure through redshift-space distortions (RSD), and the geometry of the Universe through the Alcock-Paczy\'nski (AP) effect, measuring Ωm=0.330±0.020 and σ8=0.777−0.062+0.047 for a ΛCDM cosmology. Comparing to results from a template-based method, we find that fitting the shape of the void-galaxy cross-correlation function provides more information and leads to an improvement in constraining power. In contrast, we find that errors on the AP measurements were previously underestimated if void centres were assumed to have the same response to the AP effect as galaxies - a common simplification. Overall, we recover a 28% reduction in errors for Ωm and similar errors on σ8 with our new, more comprehensive, method. Given the statistical power of future surveys including DESI and Euclid, we expect the method presented to become the new baseline for the analysis of voids in these data.
@article{arxiv.2407.03221,
title = {Modelling the BOSS void-galaxy cross-correlation function using a neural-network emulator},
author = {Tristan S. Fraser and Enrique Paillas and Will J. Percival and Seshadri Nadathur and Slađana Radinović and Hans A. Winther},
journal= {arXiv preprint arXiv:2407.03221},
year = {2025}
}
Comments
44 pages, 20 figures, 4 tables, submitted to JCAP, bold text removed