Probing massive neutrinos with the Minkowski functionals of large-scale structure

TL;DR

This paper demonstrates that Minkowski functionals of large-scale structure provide significantly improved constraints on the total neutrino mass compared to traditional power spectrum analysis, especially when combined.

Contribution

It introduces the use of Minkowski functionals to analyze large-scale structure for neutrino mass constraints, showing they outperform power spectrum alone and help break parameter degeneracies.

Findings

Minkowski functionals yield tighter neutrino mass constraints than the power spectrum.

Combining MFs with the power spectrum improves constraints by factors up to 63.

Using MFs with the 'm' field can reach a neutrino mass sensitivity of 0.0177 eV.

Abstract

Massive neutrinos suppress the growth of structure under their free-streaming scales. The effect is most prominent on small scales where the widely-used two-point statistics can no longer capture the full information. In this work, we study the signatures massive neutrinos leave on large-scale structure (LSS) as revealed by its morphological properties, which are fully described by $4$ Minkowski functionals (MFs), and quantify the constraints on the summed neutrino mass $M_{\nu}$ from the MFs, by using publicly available N-body simulations. We find the MFs provide important complementary information, and give tighter constraints on $M_{\nu}$ than the power spectrum. Specifically, depending on whether massive neutrinos are included in the density field (the `m' field) or not (the `cb' field), we find the constraint on $M_{\nu}$ from the MFs with a smoothing scale of $R_G=5 h^{-1}$Mpc is $48$ or $4$ times better than that from the power spectrum. When the MFs are combined with the power spectrum, they can improve the constraint on $M_{\nu}$ from the latter by a factor of 63 for the `m' field and 5 for the `cb' field. Notably, when the `m' field is used, the constraint on $M_{\nu}$ from the MFs can reach $0.0177$eV with a volume of $1(h^{-1}\rm Gpc)^3$, while the combination of the MFs and power spectrum can tighten this constraint to be $0.0133$eV, a $4.5\sigma$ significance on detecting the minimum sum of the neutrino masses. For the `m' field, we also find the $\sigma_8$ and $M_{\nu}$ degeneracy is broken with the MFs, leading to stronger constraints on all 6 cosmological parameters considered in this work than the power spectrum.