Precision Analysis for H0 Using Upcoming Multi-band Gravitational Wave Observations

Abstract

We investigate how multi-band gravitational wave (GW) observations can constrain the uncertainties in the Hubble parameter (H0) using primordial black holes (PBHs) as possible sources. Our framework combines scalar-induced and merger-induced GWs from PBHs, and forecasts on a combination of two future detectors Square Kilometre Array (SKA) and the Einstein Telescope (ET), enabling a multi-band analysis. We perform a statistical forecast of the PBH parameters, M PBH and f PBH, using signal-to-noise ratio (SNR) estimates and Fisher matrix analysis. Imposing SNR ≥ 1, we identify the accessible PBH parameter space and propagate these uncertainties to estimate the corresponding uncertainties in H0. For δ θi/θi ≤ 0.1, with θi M PBH(f PBH), we find δ H0 2~ km\,s-1\,Mpc-1 in a conservative approach, improving to δ H0 O(0.1)~ km\,s-1\,Mpc-1 for δ θi/θi ≤ 0.01 for an optimistic approach of precision measurement. The results are further found to be largely insensitive to the fiducial choice of the H0, with only moderate dependence on the PBH collapse efficiency. These findings demonstrate that multi-band GW observations provide an independent and complementary approach to constraining the uncertainties in H0, with the potential to provide a novel, cosmic distance ladder-independent measure of the Hubble parameter.