Using the redshift evolution of the Lyman-α effective opacity as a probe of dark matter models
Abstract
Lyman-α forest data are known to be a good probe of the small scale matter power. In this paper, we explore the redshift evolution of the observable effective optical depth τ eff (z) from the Lyman-α data as a discriminator between dark matter models that differ from the model on small scales. We consider the thermal warm dark matter (WDM) and the ultra-light axion (ULA) models for the following set of parameters: the mass of ULA, ma 10-24--5 × 10-22 \, eV and WDM mass, m wdm = 0.1 -- 4.6 \, keV. We simulate the line-of-sight HI density and velocity fields using semi-analytic methods. The simulated effective optical depth for the alternative dark matter models diverges from the model for z 3, which provides a meaningful probe of the matter power at small scales. Using likelihood analysis, we compare the simulated data with the high-resolution Lyman-α forest data in the redshift range 2 < z < 4.2. The analysis yields the following 1σ bounds on dark matter masses: m wdm > 0.7\, keV and m a > 2 × 10-23 \, eV. To further test the efficacy of our proposed method, we simulate synthetic data sets compatible with the model in the redshift range 2 ≤ z ≤ 6.5 and compare with theory. The 1σ bounds obtained are significantly tighter: m wdm > 1.5 \, keV and m a > 7 × 10-23 \, eV. Although our method provides an alternative way of constraining dark matter models, we note that these bounds are weaker than those obtained by high-resolution hydrodynamical simulations.
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