Forecasts on Interacting Dark Energy from 21-cm Angular Power Spectrum with BINGO and SKA observations

Abstract

Neutral hydrogen (HI) intensity mapping is a promising technique to probe the large-scale structure of the Universe, improving our understanding on the late-time accelerated expansion. In this work, we first scrutinize how an alternative cosmology, interacting dark energy (IDE), can affect the 21-cm angular power spectrum relative to the concordance model. We re-derive the 21-cm brightness temperature fluctuation in the context of such interaction and uncover an extra new contribution. Then we estimate the noise level of three upcoming HI intensity mapping surveys, BINGO, SKA1-MID Band\,1 and Band\,2, respectively, and employ a Fisher matrix approach to forecast their constraints on the IDE model. We find that while Planck\, 2018 maintains its dominion over early-Universe parameter constraints, BINGO and SKA1-MID Band\,2 put complementary bounding to the latest CMB measurements on dark energy equation of state w, the interacting strength λi and the reduced Hubble constant h, and SKA1-MID Band\,1 even outperforms Planck\, 2018 in these late-Universe parameter constraints. The expected minimum uncertainties are given by SKA1-MID Band\,1+Planck\,: 0.34\% on w, 0.22\% on h, 0.64\% on HI bias b HI, and an absolute uncertainty of about 3×10-4 (7×10-4) on λ1 (λ2). Moreover, we quantify the effects from systematics of the redshift bin number, redshift-space distortions, foreground residuals and uncertainties on the measured HI fraction, HI(z). Our results indicate a bright prospect for HI intensity mapping surveys in constraining IDE, whether on their own or further by synergies with other measurements.