Cosmological perturbations for two cold fluids in $\Lambda$CDM
Abstract
The cosmic large-scale structure of our Universe is comprised of baryons and cold dark matter (CDM). Yet it is customary to treat these two components as a combined single-matter fluid with vanishing pressure, which is justified only for sufficiently large scales and late times. Here we go beyond the single-fluid approximation and develop the perturbation theory for two gravitationally coupled fluids while still assuming vanishing pressure. We mostly focus on perturbative expansions in powers of (or ), the linear structure growth of matter in a CDM Universe with cosmological constant . We derive in particular (1) explicit recursion relations for the two fluid densities, (2) complementary all-order results in the Lagrangian-coordinates approach, as well as (3) the associated component wavefunctions in a semi-classical approach to cosmic large-scale structure. In our companion paper (Hahn et al. 2020) we apply these new theoretical results to generate novel higher-order initial conditions for cosmological hydrodynamical simulations.
Cite
@article{arxiv.2008.09123,
title = {Cosmological perturbations for two cold fluids in $\Lambda$CDM},
author = {Cornelius Rampf and Cora Uhlemann and Oliver Hahn},
journal= {arXiv preprint arXiv:2008.09123},
year = {2020}
}
Comments
15 pages + appendices, one figure, MNRAS in press