Redshift-space galaxy bispectrum in presence of massive neutrinos: A multipole expansion approach for Euclid

Abstract

Massive neutrinos imprint distinctive signatures on the evolution of cosmic structures, notably suppressing small-scale clustering. We investigate the impact of massive neutrinos on the galaxy bispectrum in redshift-space, adopting a spherical harmonic multipole decomposition BLm(k1, μ, t), that captures the full angular dependence. We develop an analytical and numerical framework incorporating neutrino-corrected perturbation theory kernels and redshift-space distortions. Our results demonstrate that the linear triangle configurations are particularly sensitive to massive neutrinos, with deviations reaching up to 2\% for a total mass Σ m = 0.12\,eV. To assess detection prospects in galaxy surveys like Euclid, we compute the signal-to-noise ratio (SNR) for individual multipoles, including the effects of Finger-of-God damping and shot noise. The neutrino-induced signatures in B00 and B20 are found to be detectable with SNR 5 across a range of configurations, even after accounting for small-scale suppression. Higher-order multipoles such as B21 and B22 are moderately sensitive, with SNR (2-3) in squeezed limits, while hexadecapole moments are more suppressed but still exhibit measurable signals at high k1. Additionally, the SNR generally increases with wave number k1, particularly for squeezed and stretched triangles, suggesting that access to smaller scales significantly enhances detection prospects. Our study highlights the potential of the redshift-space bispectrum multipoles as sensitive probes of massive neutrinos, complementing traditional power spectrum analyses, and underscores the importance of angular information and higher-order statistics for galaxy surveys.