부산대학교 도서관

Understanding the survival of gas within subhalos under various astrophysical processes is crucial for elucidating cosmic structure formation and evolution. We study the resilience of gas in subhalos, focusing on the impact of tidal and ram pressure stripping through hydrodynamic simulations. Our results uncover significant gas stripping primarily driven by ram pressure effects, which also profoundly influence the gas distribution within these subhalos. Notably, despite their vulnerability to ram pressure effects, the low-mass subhalos can play a pivotal role in influencing the observable characteristics of cosmic structures due to their large abundance. Specifically, we explore the application of our findings to the 21 cm forest, showing how the survival dynamics of gas in subhalos can modulate the 21 cm optical depth, a key probe for detecting minihalos in the pre-reionization era. (abridged) In this work, we further investigate the contribution of subhalos to the 21 cm optical depth with hydrodynamics simulations, particularly highlighting the trajectories and fates of subhalos within mass ranges of \(10^{4-6} M_{\odot}h^{-1}\) in a host halo of \(10^7 M_{\odot}h^{-1}\). Despite their susceptibility to ram pressure stripping, the contribution of abundant low-mass subhalos to the 21-cm optical depth is more significant than that of their massive counterparts primarily due to their greater abundance. We find that the 21-cm optical depth can be increased by a factor of approximately two due to the abundant low-mass subhalos. (abridged) Our work provides critical insights into the gas dynamics within subhalos in the early Universe, highlighting their resilience against environmental stripping effects, and their impact on observable 21-cm signals.