Abstract The 21 cm line of hydrogen is the most promising probe of the Dark Ages and Cosmic Dawn. We combine hydrodynamical simulations with a large-scale grid in order to calculate the effect of nonlinear structure formation on the large-scale 21 cm power spectrum, focusing on redshifts z = 20–40. As the clumping effect arises from small-scale density fluctuations, it offers a unique opportunity to probe the standard cold dark matter model in a new regime and thus potentially investigate the properties of dark matter. To this end, we also study a warm dark matter–like model with a Gaussian cutoff on a scale of 50 kpc. We find that clumping has a significant impact on the large-scale 21 cm power spectrum, requiring a substantial correction to standard theoretical predictions. For example, for the Dark Ages case at z = 30 and wavenumber k = 0.05 Mpc −1 , small-scale clustering enhances the 21 cm power spectrum by 13%. Once Ly α coupling kicks in due to the first stars, the 21 cm signal strengthens, and the effect of clumping grows; it suppresses the observable power spectrum at z = 20 by 45%, while the warm dark matter–like model has less than half the clumping impact. The clumping effect is significantly higher than the sensitivity of the planned Square Kilometre Array AA ⋆ configuration, by up to a factor of 20 for standard cold dark matter, though detection will require separation from foregrounds and from astrophysical contributions to the 21 cm power spectrum.
Sikder et al. (Fri,) studied this question.
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