English

The Hot Dark Matter

High Energy Physics - Phenomenology 2007-05-23 v1

Abstract

There is a puzzling contradiction: direct observations favor a low-mass-density universe (0.2Ωm0.60.2\le\Omega_m\le0.6), but the only model which fits universe structure over more than three orders of magnitude in distance scale has a mix of hot (neutrino) and cold dark matter providing a critical density universe. Models of an open universe (low Ωm\Omega_m) or one adding a cosmological constant (Λ\Lambda) to provide a critical energy density (Ωm+ΩΛ=1\Omega_m+ \Omega_\Lambda=1) have probabilities of <103<10^{-3}. Two-neutrino dark matter works better than having the needed 5\sim5 eV of neutrino mass in one species of neutrino, and this is consistent with the only model which fits all present indications for neutrino mass: νμντ\nu_\mu\to\nu_\tau accounting for the atmospheric anomaly (with νμ\nu_\mu and ντ\nu_\tau being the hot dark matter), νˉμνˉe\bar\nu_\mu\to\bar\nu_e being observed by LSND, and νeνs\nu_e\to\nu_s explaining the solar νe\nu_e deficit. The LSND/KARMEN results are consistent with the needed mass of hot dark matter. Further support for this mass pattern is provided by the need for the sterile neutrino, νs\nu_s, to make possible heavy-element nucleosynthesis in supernovae. It is a fascinating question as to whether the hot dark matter paradox will be resolved by better measurements or by the introduction of new physics.

Keywords

Cite

@article{arxiv.hep-ph/9910349,
  title  = {The Hot Dark Matter},
  author = {David O. Caldwell},
  journal= {arXiv preprint arXiv:hep-ph/9910349},
  year   = {2007}
}

Comments

10 pages, 1 figure, talk given at 23rd Johns Hopkins Workshop, "Neutrinos in the Next Millenium"