Cosmology and neutrino mass with the Minimum Spanning Tree

Abstract

The information content of the minimum spanning tree (MST), used to capture higher-order statistics and information from the cosmic web, is compared to that of the power spectrum for a model. The measurements are made in redshift space using haloes from the Quijote simulation of mass ≥ 3.2× 1013\,h-1 M in a box of length L box=1\,h-1 Gpc. The power spectrum multipoles (monopole and quadrupole) are computed for Fourier modes in the range 0.006 < k < 0.5\, h Mpc-1. For comparison the MST is measured with a minimum length scale of l13\,h-1 Mpc. Combining the MST and power spectrum allows for many of the individual degeneracies to be broken; on its own the MST provides tighter constraints on the sum of neutrino masses M and cosmological parameters h, n s, and b but the power spectrum alone provides tighter constraints on m and σ8. Combined we find constraints that are a factor of two (or greater) on all parameters with respect to the power spectrum (for M there is a factor of four improvement). These improvements appear to be driven by the MST's sensitivity to small scale clustering, where the effect of neutrino free-streaming becomes relevant, and high-order statistical information in the cosmic web. The MST is shown to be a powerful tool for cosmology and neutrino mass studies, and therefore could play a pivotal role in ongoing and future galaxy redshift surveys (such as DES, DESI, Euclid, and Rubin-LSST).