Viability of complex self-interacting scalar field as dark matter
arXiv:1101.0028 · doi:10.1016/j.physletb.2010.12.064
Abstract
We study the viability of a complex scalar field $Ï$ with self-interacting potential $ V = m^Ï_0/2 \, |Ï|^2 + h \, |Ï|^4$ as dark matter. The scalar field is produced at reheating through the decay of the inflaton field and then, due to the self-interaction, a Bose-Einstein condensate of $Ï$ particles forms. The condensate represents dark matter in that model. We analyze the cosmological evolution of the model, stressing how, due to the presence of the self-interaction, the model naturally admits dark matter domination at late times, thus avoiding any fine tuning on the energy density of the scalar field at early times. Finally we give a lower bound for the size of dark matter halos at present time and we show that our model is compatible with dark matter halos greater than $0.1 \, Kpc$ and with BBN and CMB bounds on the effective number of extra neutrinos $Î_ν^{eff}$. Therefore, the model is viable and for $h\simeq 10^{-4}-10^{-12}$ one obtains a mass $m^Ï\simeq m^Ï_0 \simeq 1-10^{-2} \, eV$ for dark matter particles from radiation-matter equality epoch to present time, but at temperatures $T_γ\gg 10 \, eV$, where $T_γ$ is the photons temperature, thermal corrections to $m^Ï_0$ due to the self-coupling $h$ are dominant.
7 pages, some reference added