CRASHalpha: coupling continuum and line radiative transfer

Abstract

In this paper we present CRASHalpha, the first radiative transfer code for cosmological application that follows the parallel propagation of Lyalpha and ionizing photons. CRASHalpha is a version of the continuum radiative transfer code CRASH with a new algorithm to follow the propagation of Lyalpha photons through a gas configuration whose ionization structure is evolving. The implementation introduces the time evolution for Lyalpha photons (a feature commonly neglected in line radiative transfer codes) and, to reduce the computational time needed to follow each scattering, adopts a statistical approach to the Lyalpha treatment by making extensive use of pre-compiled tables. With this statistical approach we experience a drastic increase of the computational speed and, at the same time, an excellent agreement with the full Lyalpha radiative transfer computations of the code MCLyalpha. We find that the emerging spectra keep memory of the ionization history which generates a given ionization configuration of the gas and, to properly account for this effect, a self-consistent joint evolution of line and ionizing continuum radiation as implemented in CRASHalpha is necessary. A comparison between the results from our code and from Lyalpha scattering alone on a fixed HI density field shows that the extent of the difference between the emerging spectra depends on the particular configuration considered, but it can be substantial and can thus affect the physical interpretation of the problem at hand. These differences should furthermore be taken into account when computing the impact of the Lyalpha radiation on e.g. the observability of the 21 cm line from neutral hydrogen at epochs preceeding complete reionization.