Signatures of Small-scale Structure of the Pre-reionization Intergalactic Medium in z7 Quasar Proximity Zones
Abstract
The small-scale structure of baryons in the intergalactic medium is intimately linked to their past thermal history. Prior to the 104 K photoheating during the epoch of reionization, cold baryons may have closely traced the clumpy cosmic web of dark matter down to scales as low as 1 comoving kpc, depending on the degree of heating by the X-ray background. After the passage of the ionization front, this clumpy structure can persist for 108 years. The strong Lyα damping wings detected towards a few of the highest redshift quasars, in addition to their smaller-than-expected Lyα-transmissive proximity zones, suggest that they have ionized and heated the foreground intergalactic medium less than 107 years ago. Signatures of the pre-reionization small-scale structure should thus persist in their intergalactic surroundings. Here we explore how the persistence of this clumpy structure can affect the statistics of Lyα transmission inside the transparent proximity zones of z7 quasars by post-processing a suite of small-volume hydrodynamical simulations with 1D ionizing radiative transfer. We find that the Lyα flux power spectrum and flux PDF statistics of ten z=7.5 proximity zones, with realistic observational parameters, could distinguish the gaseous structure of a T IGM2 K CDM model from warm dark matter models with particle masses m WDM>10 keV and X-ray heated models with f Xf abs>0.1 (T IGM(z=7.5)275 K) at the 2σ level.
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