Probing Cosmology with 92 Localized Fast Radio Bursts and DESI BAO

Abstract

Recent baryon acoustic oscillation (BAO) measurements from the Dark Energy Spectroscopic Instrument (DESI) collaboration, combined with the cosmic microwave background (CMB) and type Ia supernovae (SNe Ia) observations, suggest a preference for dynamical dark energy (DDE) with w0>-1 and wa<0. Given the cosmological origin of fast radio bursts (FRBs), the combination of their dispersion measures and host galaxy redshifts makes localized FRBs a valuable tool for probing cosmology. Using an updated sample of 92 localized FRBs, along with DESI BAO, PlantheonPlus and CMB data, we constrain the dark energy (DE) equation of state (EoS) under the Chevallier-Polarski-Linder (CPL) parameterization. We find that even without incorporating CMB data, DDE remains preferred with w0 = -0.855 +0.084-0.084 and wa = -1.174+0.462-0.491 at a confidence level of 2.5 σ. A joint analysis constrains these to be w0 = -0.784+0.064-0.064 and wa = -0.872+0.269-0.278, showing a discrepancy with at a 3.1σ level. Furthermore, using localized FRBs alone, we estimate the Hubble constant H0 to be 69.04+2.30-2.07 and 75.61+2.23-2.07 \, km \, s-1 \, Mpc-1, assuming the Galactic electron density models to be NE2001 (Cordes \& Lazio) and YMW16 (Yao et al.), respectively. Thus, accurate accounting of the Galactic dispersion measure is crucial for resolving the Hubble tension with FRBs. Future BAO measurements, next-generation CMB experiments, and more localized FRBs will further constrain the DE EoS and the cosmological parameters.