Peculiar velocities in the $\Lambda$CDM universe
Abstract
We present a unified analysis of the linear evolution of peculiar-velocity perturbations in the distribution of pressureless matter after recombination. Our study is carried out within the framework of full general relativity and encompasses both the earlier Einstein-de Sitter epoch and the subsequent -dominated phase. Starting from a non-interacting, non-comoving mixture of radiation and dust, we derive the generalized differential equations governing the evolution of these velocity perturbations. We confirm that linear peculiar velocities () grow as throughout the Einstein-de Sitter era. In contrast, during a later phase of increasing -contribution, we find that the growth of the peculiar-velocity field is progressively suppressed, before reversing to decay. Nevertheless, part of the earlier velocity growth persists to the present. Hence, bulk-flow velocities at intermediate redshifts are expected to exceed those predicted by the CDM model, followed by a decline in their value at lower redshifts. Interestingly, such peculiar-velocity profiles have already been reported in the literature.
Cite
@article{arxiv.2604.24974,
title = {Peculiar velocities in the $\Lambda$CDM universe},
author = {Evanthia Patliaka and Christos G. Tsagas},
journal= {arXiv preprint arXiv:2604.24974},
year = {2026}
}
Comments
12 pages, 3 figures