Effective Theory for Electroweak Doublet Dark Matter
Abstract
We perform a detailed study of an effective field theory which includes the Standard Model particle content extended by a pair of Weyl fermionic SU(2)-doublets with opposite hypercharges. A discrete symmetry guarantees that a linear combination of the doublet components is stable and can act as a candidate particle for Dark Matter. The dark sector fermions interact with the Higgs and gauge bosons through renormalizable operators, and non-renormalizable operators that appear after integrating out extra degrees of freedom above the TeV scale. We study collider, cosmological and astrophysical probes for this effective theory of Dark Matter. We find that a WIMP with a mass nearby to the electroweak scale, and thus observable at LHC, is consistent with collider and astrophysical data only when fairly large magnetic dipole moment transition operators with the gauge bosons exist, together with moderate Yukawa interactions.
Cite
@article{arxiv.1607.05040,
title = {Effective Theory for Electroweak Doublet Dark Matter},
author = {Athanasios Dedes and Dimitrios Karamitros and Vassilis C. Spanos},
journal= {arXiv preprint arXiv:1607.05040},
year = {2016}
}
Comments
46 pages, v2: references and related comments added, v3: references added, discussion on LHC searches expanded, a discussion on the Sommerfeld enhancement added, matches published version