Asymmetric condensed dark matter
Abstract
We explore the viability of a boson dark matter candidate with an asymmetry between the number densities of particles and antiparticles. A simple thermal field theory analysis confirms that, under certain general conditions, this component would develop a Bose-Einstein condensate in the early universe that, for appropriate model parameters, could survive the ensuing cosmological evolution until now. The condensation of a dark matter component in equilibrium with the thermal plasma is a relativistic process, hence the amount of matter dictated by the charge asymmetry is complemented by a hot relic density frozen out at the time of decoupling. Contrary to the case of ordinary WIMPs, dark matter particles in a condensate must be lighter than a few tens of eV so that the density from thermal relics is not too large. Big-Bang nucleosynthesis constrains the temperature of decoupling to the scale of the QCD phase transition or above. This requires large dark matter-to-photon ratios and very weak interactions with standard model particles.
Cite
@article{arxiv.1502.07354,
title = {Asymmetric condensed dark matter},
author = {Anthony Aguirre and Alberto Diez-Tejedor},
journal= {arXiv preprint arXiv:1502.07354},
year = {2016}
}
Comments
30 pages, 1 figure. Some improvements with respect to the previous version. To appear in JCAP