📝 SummarXiv

Abstract

Lyman-Alpha (Lya) photons emitted in star-forming regions inside galaxies experience a complex radiative transfer process until they reach the observer. The Lya line profile that we measured on Earth is, thus, the convolution of the gas properties in the interstellar (ISM), circumgalactic (CGM), and intergalactic medium (IGM). We make use of the open source package zELDA (redshift Estimator for Line profiles of Distant Lyman-Alpha emitters) to disentangle the galactic and IGM components of the Lya profiles to study both the evolution of the intrinsic galactic emission and the IGM transmission across cosmic time. zELDA includes different artificial neural networks that reconstruct IGM attenuated Lya line profiles. These models are trained using mock Lya line profiles. A Monte Carlo radiative transfer code computes the galactic component for the so-called thin shell model. Moreover, the IGM component is included through the IGM transmission curves generated from the IllustrisTNG100 cosmological galaxy formation simulation. We recover their intrinsic galactic spectra by applying the zELDA to 313 Lya line profiles observed with HST/COS and MUSE. Sources at z < 0.5 show weak IGM attenuation, while at z > 3, ZELDA reveals significant IGM suppression of the blue peak in several sources. After separating the IGM effects, the stacked intrinsic galactic Lya profiles show a minimal evolution from z = 0 to 6. The mean IGM transmission for z < 0.5 in HST/COS data exceeds 90%, while the MUSE data show an evolution from 0.85 at z = 3.0 to 0.55 at z = 5.0.