Euclid preparation: Testing multi-field inflation with galaxy power spectrum and bispectrum

Abstract

Primordial non-Gaussianity (PNG) is a powerful probe of the origin of cosmic structure. Stage-IV surveys like will measure galaxy 2- and 3-point clustering at high signal-to-noise, whose exploitation requires robust joint analysis. We prepare for Euclid's spectroscopic sample by validating a redshift-space power-spectrum and bispectrum pipeline (one-loop P, tree-level B) on Euclid-like mocks from Abacus-PNG N-body simulations with Gaussian and local-PNG initial conditions, using a halo occupation distribution (HOD) tuned to Euclid Flagship 2. We stress-test analysis choices -- PNG-bias parametrisation, priors, and scale cuts -- and perform null tests without PNG. In a `prior-agnostic setup', detection of the dominant PNG term f NL \, bϕ in single redshift bins is difficult; nevertheless, the bispectrum provides constraints on other PNG combinations that partially lift degeneracies. We propose a physically motivated prior on bϕ that yields unbiased f NL while accounting for theory uncertainty, and determine scale cuts that give unbiased ΛCDM and f NL. With V eff=16\,h-3\, Gpc3 across four snapshots (0.8 z1.7), our likelihood analyses recover <1σ bias in f NL and ΛCDM. At fixed cuts, B alone reduces σ(f NL) by 29--46\% relative to P, and joint power spectrum-bispectrum analysis tightens a further 8--13\%; the cumulative gain from z=0.8 to 1.7 is 2.3 for the joint case. The bispectrum quadrupole is key. Our strongest results are at z=1.7: 1.9σ for f NL \, bϕ (prior-agnostic) and 2.35σ for f NL (prior-based). Joint analyses thus offer strong prospects for testing multi-field inflation, pending end-to-end validation in the full Euclid geometry with observational systematics.