Kalliopi Petraki, Mark Trodden, Raymond R. Volkas
The similar cosmological abundances observed for visible and dark matter
suggest a common origin for both. By viewing the dark matter density as a
dark-sector asymmetry, mirroring the situation in the visible sector, we show
that the visible and dark matter asymmetries may have arisen simultaneously
through a first-order phase transition in the early universe. The dark
asymmetry can then be equal and opposite to the usual visible matter asymmetry,
leading to a universe that is symmetric with respect to a generalised baryon
number. We present both a general structure, and a precisely defined example of
a viable model of this type. In that example, the dark matter is atomic as well
as asymmetric, and various cosmological and astrophysical constraints are
derived. Testable consequences for colliders include a Z' boson that couples
through the B-L charge to the visible sector, but also decays invisibly to dark
sector particles. The additional scalar particles in the theory can mix with
the standard Higgs boson and provide other striking signatures.
View original:
http://arxiv.org/abs/1111.4786
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