Studying dark gaps in Ly-α forest transmission with large reionization simulations

Abstract

The physical conditions of the intergalactic medium (IGM) during the final stages of cosmic reionization (z5.0-6.0) are not yet fully understood. Recent reports of unexpectedly large-scale ( 150 h-1cMpc) correlation in Ly-α transmission flux using extended XQR-30 quasar spectra pose interesting challenges on the reionization end stages. In this work, we investigate the Ly-α forest dark-gap distribution (defined as regions with transmitted flux below 0.05) as another sensitive tracer of the IGM, using an efficient, large-volume ( 1 ~Gpc) simulation framework. By constructing a suite of physically motivated model variants (i.e, varying the reionization redshift, IGM temperature, and ionizing-photon mean free path), we generate synthetic sightlines and compare their predicted cumulative distribution of dark gaps with that of observed spectra (at redshift intervals of Δz=0.2). We find that most of the models achieve qualitatively consistent agreement with the data. The scenario involving a slightly later reionization completion (z 5.4) provides the closest match, while a short constant mean free path model is disfavored by the data at lower redshifts. These findings give qualitative support for the emerging scenario of reionization end extending to z5.7, although they can not rule out a slightly early reionization with enhanced post-ionization ultraviolet (UV) background fluctuations. A similar conclusion arises from the redshift distribution of long dark gap (L 30 ~h-1cMpc) fraction. However, the model variants are still not able to reproduce the observed strong flux correlations at unusually large scales, which remains open for further investigations.