Radiative transfer effects on the Lyα forest

A. Maselli, A. Ferrara

Research output: Contribution to journalArticle

Abstract

Strong observational evidence for a fluctuating ultraviolet background (UVB) has been accumulating through a number of studies of the H I and He II Lya forest as well as accurate intergalactic medium (IGM) metallicity measurements. UVB fluctuations could arise both from the inhomogeneous distribution of the ionizing sources and/or from radiative transfer (RT) through the filamentary IGM. In this study we investigate, via numerical simulations, the role of RT effects, such as shadowing, self-shielding and filtering of the ionizing radiation, in giving rise to a fluctuating UVB. We focus on possible detectable signatures of these effects on quantities derived from Lyα forest spectra, as photoionization rate fluctuations, η(≡NHeII/NHI) parameter distributions and the IGM temperature at z ≈ 3. We find that RT induces fluctuations up to 60 per cent in the UVB, which are tightly correlated to the density field. The UVB mean intensity is progressively suppressed toward higher densities and photon energies above 4 Ryd, due to the high He η with opacity. Shielding of overdense regions (Δ ≳ 5) from cosmic He II ionizing radiation produces a decreasing trend of η with overdensity. Furthermore, we find that the mean η value inferred from HI-He II Lyα forest observations can be explained only by properly accounting for the actual IGM opacity. We outline and discuss several implications of our findings.

Original languageEnglish
Pages (from-to)1429-1440
Number of pages12
JournalMonthly Notices of the Royal Astronomical Society
Volume364
Issue number4
DOIs
Publication statusPublished - Dec 21 2005

Keywords

  • Cosmology: theory
  • Diffuse radiation
  • Large-scale structure of Universe
  • Methods: numerical
  • Radiative transfer

ASJC Scopus subject areas

  • Space and Planetary Science

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