English

Primordial fluctuations without scalar fields

Cosmology and Nongalactic Astrophysics 2010-04-06 v2

Abstract

We revisit the question of whether fluctuations in hydrodynamical, adiabatical matter could explain the observed structures in our Universe. We consider matter with variable equation of state w=p0/\ep0w=p_0/\ep_0 and a concomitant (under the adiabatic assumption) density dependent speed of sound, csc_s. We find a limited range of possibilities for a set up when modes start inside the Hubble radius, then leaving it and freezing out. For expanding Universes, power-law w(\ep0)w(\ep_0) models are ruled out (except when cs2w1c_s^2\propto w \ll 1, requiring post-stretching the seeded fluctuations); but sharper profiles in csc_s do solve the horizon problem. Among these, a phase transition in csc_s is notable for leading to scale-invariant fluctuations if the initial conditions are thermal. For contracting Universes all power-law w(\ep0)w(\ep_0) solve the horizon problem, but only one leads to scale-invariance: w\ep02w\propto \ep_0^2 and cs\ep0c_s\propto \ep_0. This model bypasses a number of problems with single scalar field cyclic models (for which ww is large but constant).

Keywords

Cite

@article{arxiv.0907.1772,
  title  = {Primordial fluctuations without scalar fields},
  author = {J. Magueijo and J. Noller},
  journal= {arXiv preprint arXiv:0907.1772},
  year   = {2010}
}
R2 v1 2026-06-21T13:23:32.092Z