Crucial Factors for Ly{\alpha} Transmission in the Reionizing Intergalactic Medium: Infall Motion, HII Bubble Size, and Self-shielded Systems

Using the CoDa II simulation, we study the Ly\(\alpha\) transmissivity of the intergalactic medium (IGM) during reionization. At \(z>6\), a typical galaxy without an active galactic nucleus fails to form a proximity zone around itself due to the overdensity of the surrounding IGM. The gravitation...

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Bibliographic Details
Published in:arXiv.org 2021-12
Main Authors: Park, Hyunbae, Jung, Intae, Song, Hyunmi, Ocvirk, Pierre, Shapiro, Paul R, Taha Dawoodbhoy, Iliev, Ilian T, Ahn, Kyungjin, Bianco, Michele, Hyo Jeong Kim
Format: Article
Language:English
Subjects:
Active galactic nuclei
Attenuation
Damping
Galaxies
Intergalactic media
Ionization
Opacity
Red shift
Resonance absorption
Stars & galaxies
Supernovae
Transmissivity
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Summary:Using the CoDa II simulation, we study the Ly\(\alpha\) transmissivity of the intergalactic medium (IGM) during reionization. At \(z>6\), a typical galaxy without an active galactic nucleus fails to form a proximity zone around itself due to the overdensity of the surrounding IGM. The gravitational infall motion in the IGM makes the resonance absorption extend to the red side of Ly\(\alpha\), suppressing the transmission up to roughly the circular velocity of the galaxy. In some sight lines, an optically thin blob generated by a supernova in a neighboring galaxy results in a peak feature, which can be mistaken for a blue peak. Redward of the resonance absorption, the damping-wing opacity correlates with the global IGM neutral fraction and the UV magnitude of the source galaxy. Brighter galaxies tend to suffer lower opacity because they tend to reside in larger HII regions, and the surrounding IGM transmits redder photons, which are less susceptible to attenuation, owing to stronger infall velocity. The HII regions are highly nonspherical, causing both sight-line-to-sight-line and galaxy-to-galaxy variation in opacity. Also, self-shielded systems within HII regions strongly attenuate the emission for certain sight lines. All these factors add to the transmissivity variation, requiring a large sample size to constrain the average transmission. The variation is largest for fainter galaxies at higher redshift. The 68\% range of the transmissivity is similar to or greater than the median for galaxies with \(M_{\rm UV}\ge-21\) at \(z\ge7\), implying that more than a hundred galaxies would be needed to measure the transmission to 10\% accuracy.
ISSN:2331-8422
DOI:10.48550/arxiv.2105.10770