Cosmological constraints from the DESI DR1 Bispectrum Full-Shape and DR2 BAO

Abstract

We present cosmological constraints from the combination of DESI DR1 full-shape measurements, including for the LRG bispectrum, and DESI DR2 BAO data. The joint analysis accounts for cross-covariance using mocks, while ShapeFit compression mitigates prior volume effects that hinder beyond-ΛCDM analyses. In ΛCDM, the bispectrum (P+B) shifts σ8 up by 1.1σ and S8 by 1.2σ, reducing their uncertainties by 26\% and 28\%, respectively. For w0waCDM, DESI-only analyses with the bispectrum shift dark energy parameters toward ΛCDM, staying consistent with a cosmological constant within 1σ. Adding CMB creates a preference for evolving dark energy: DESI+CMB (P+B) shows a 2.8σ deviation from ΛCDM. Including DES-Dovekie supernovae alone reduces this to 1.6σ, while the full combination DESI+CMB+DES-Dovekie gives 3.1σ, driven primarily by the CMB. The bispectrum consistently weakens evidence for time-varying dark energy relative to power-spectrum-only analyses. The bispectrum also enhances sensitivity to massive neutrinos: in DESI-only analysis, the power-spectrum-only posterior for Σ mν is consistent with zero, whereas adding the bispectrum yields a mean of 0.260.17~eV and a 95\% upper limit of 0.57~eV, shifting the peak into the positive region and agreeing with oscillation lower bounds. For modified gravity, the bispectrum further constrains μ0 = 0.120.49 from DESI-only data, consistent with general relativity. Our analysis shows that accounting for cross-dataset covariances and avoiding prior volume effects yields robust constraints, with the bispectrum raising amplitude parameters and tightening their uncertainties.