Euclid preparation. Decomposing components of the extragalactic background light using multi-band intensity mapping cross-correlations

Abstract

The extragalactic background light (EBL) fluctuations in the optical/near-IR encode the cumulative integrated galaxy light (IGL), diffuse intra-halo light (IHL), and high-z sources from the epoch of reionisation (EoR), but they are difficult to disentangle with auto-spectra alone. We aim to decompose the EBL into its principal constituents using multi-band intensity mapping combined with cosmic shear and galaxy clustering. We develop a joint halo-model framework in which IHL follows a mass- and redshift-dependent luminosity scaling, IGL is set by an evolving Schechter luminosity function, and EoR emission is modelled with Pop II/III stellar emissivities and a binned star-formation efficiency. Using mock surveys in a flat ΛCDM cosmology with ten spectral bands spanning 0.75-5.0 μm in the NEP deep fields over about 100°2 with source detections down to AB=20.5 for masking, and six redshift bins to z=2.5, we fit auto- and cross-power spectra using a MCMC method. The combined SPHEREx×Euclid analysis recovers all fiducial parameters within 1σ and reduces 1σ uncertainties on IHL parameters by 10-35% relative to SPHEREx EBL-only, while EoR star-formation efficiency parameters improve by 20-35%. Cross-correlations reveal a stronger coupling of IHL than IGL to the shear field, enhancing component separation; conversely, the EoR contribution shows negligible correlation with cosmic shear and galaxy clustering, aiding its isolation in the EBL. Relative to the SPHEREx EBL-only case, the inferred IHL fraction as a function of halo mass is significantly tightened over 1011-1014 M, with uncertainties reduced by 5-30%, and the resulting star-formation rate density constraints extend to z 11, with uncertainty reductions of 22-31%.