Cosmic baryon census with fast radio bursts and gravitational waves

Abstract

The cosmic baryon density fraction ( b) is intrinsically correlated with the Hubble constant (H0) through the critical density of the Universe. In the context of the decade-long H0 tension, the significant discrepancy between early- and late-Universe measurements of H0 implies that fixing its value or imposing an external prior could bias the baryon census. To address this concern, we construct a late-Universe probe framework that unifies fast radio bursts (FRBs) and gravitational-wave (GW) standard sirens, which can respectively resolve the ''missing baryon'' problem and the H0 tension through their dispersion measures (DMs) and absolute luminosity distances. By combining 104 localized FRBs with 47 GW events, we obtain an H0-free measurement of b=0.04880.0064 (1σ), in concordance with early-Universe observations of CMB + BBN. The result is tightly anchored by GW-inferred H0 through the strong b-H0 degeneracy. Although the current precision ( 13\%) is limited by sample size, the growing detections of both FRBs and GWs will make their synergy a powerful probe of low-redshift cosmology.