On dark matter - dark radiation interaction and cosmic reionization

TL;DR

This paper explores how interactions between dark matter and dark radiation could influence cosmic reionization, providing constraints on such dark sector models using Planck data and comparing with warm dark matter scenarios.

Contribution

It introduces a novel analysis of dark matter-dark radiation interactions' impact on reionization, deriving new constraints within the ETHOS framework and contrasting with warm dark matter limits.

Findings

Dark matter-dark radiation interactions suppress small-scale structures.

Constraints on interaction strength parameter a_4 are established.

Reionization history can be used to probe dark sector physics.

Abstract

An intriguing possibility for the dark sector of our universe is that the dark matter particle could interact with a dark radiation component. If the non-gravitational interactions of the dark matter and dark radiation species with Standard Model particles are highly suppressed, then astrophysics and cosmology could be our only windows into probing the dynamics of such a dark sector. It is well known that such dark sectors would lead to suppression of small scale structure, which would be constrained by measurements of the Lyman-$\alpha$ forest. In this work we consider the cosmological signatures of such dark sectors on the reionization history of our universe. Working within the "ETHOS" (effective theory of structure formation) framework, we show that if such a dark sector exists in our universe, the suppression of low mass dark matter halos would also reduce the total number of ionizing photons, thus affecting the reionization history of our universe. We place constraints on the interaction strengths within such dark sectors by using the measured value of the optical depth from the Planck satellite, as well as from demanding a successful reionization history. We compare and contrast such scenarios with warm dark matter scenarios which also suppress structure formation on small scales. In a model where dark matter interacts with a sterile neutrino, we find a bound on the ETHOS parameter $a_4\lesssim 1.2\times10^6\textrm{ Mpc}^{-1}$. For warm dark matter models, we constrain the mass $m_{\textrm{WDM}}\gtrsim 0.7\textrm{ keV}$, which is comparable to bounds obtained from Lyman-$\alpha$ measurements. Future 21-cm experiments will measure the global history of reionization and the neutral hydrogen power spectrum, which could either lead to stronger constraints or discovery of secret dark sector interactions.