English

The ACCEL$^2$ project: simulating Lyman-$\alpha$ forest in large-volume hydrodynamical simulations

Cosmology and Nongalactic Astrophysics 2024-11-14 v2 Computational Physics

Abstract

Cosmological information is usually extracted from the Lyman-α\alpha forest correlations using only either large-scale information interpreted through linear theory or using small-scale information interpreted by means of expensive hydrodynamical simulations. A complete cosmological interpretation of the 3D correlations at all measurable scales is challenged by the need of more realistic models including the complex growth of non-linear small scales that can only be studied within large hydrodynamical simulations. Past work were often limited by the trade off between the simulated cosmological volume and the resolution of the low-density intergalactic medium from which the Lyman-α\alpha signal originates. We conduct a suite of hydrodynamical simulations of the intergalactic medium, including one of the largest Lyman-α\alpha simulations ever performed in terms of volume (640 h1Mpch^{-1}\mathrm{Mpc}), alongside simulations in smaller volumes with resolutions up to 25 h1kpch^{-1}\mathrm{kpc}, which will be further improved to show resolution convergence in future studies. We compare the 3D Lyman-α\alpha power spectra predicted by those simulations to different non-linear models. The inferred Lyman-α\alpha bias and redshift space distortion (RSD) parameters, bαb_\alpha and βα\beta_\alpha are in remarkable agreement with those measured in SDSS and DESI data. We find that, contrary to intuition, the convergence of large-scale modes of the 3D Lyman-α\alpha power spectra, which determines βα\beta_\alpha, is primarily influenced by the resolution of the simulation box through mode coupling, rather than the box size itself. Finally, we study the BAO signal encoded in the 3D Lyman-α\alpha power spectra. For the first time with a hydrodynamical simulation, we clearly detect the BAO signal, however we only marginally detect its damping, associated with the non-linear growth of the structures.

Keywords

Cite

@article{arxiv.2407.04473,
  title  = {The ACCEL$^2$ project: simulating Lyman-$\alpha$ forest in large-volume hydrodynamical simulations},
  author = {Solène Chabanier and Corentin Ravoux and Lucas Latrille and Jean Sexton and Éric Armengaud and Julian Bautista and Tyann Dumerchat and Zarija Lukić},
  journal= {arXiv preprint arXiv:2407.04473},
  year   = {2024}
}

Comments

17 pages, 12 figures

R2 v1 2026-06-28T17:30:11.873Z