English

Complex Scalar DM in a B-L Model

High Energy Physics - Phenomenology 2014-10-08 v1

Abstract

In this work, we implement a complex scalar Dark Matter (DM) candidate in a U(1)BLU(1)_{B-L} gauge extension of the Standard Model. The model contains three right handed neutrinos with different quantum numbers and a rich scalar sector, with extra doublets and singlets. In principle, these extra scalars can have VEVs (VΦV_{\Phi} and VϕV_{\phi} for the extra doublets and singlets, respectively) belonging to different energy scales. In the context of ζVΦVϕ1\zeta\equiv\frac{V_{\Phi}}{V_{\phi}}\ll1, which allows to obtain naturally light active neutrino masses and mixing compatible with neutrino experiments, the DM candidate arises by imposing a Z2Z_{2} symmetry on a given complex singlet, ϕ2\phi_{2}, in order to make it stable. After doing a study of the scalar potential and the gauge sector, we obtain all the DM dominant processes concerning the relic abundance and direct detection. Then, for a representative set of parameters, we found that a complex DM with mass around 200200 GeV, for example, is compatible with the current experimental constraints without resorting to resonances. However, additional compatible solutions with heavier masses can be found in vicinities of resonances. Finally, we address the issue of having a light CP-odd scalar in the model showing that it is safe concerning the Higgs and the ZμZ_{\mu} boson invisible decay widths, and also the energy loss in stars astrophysical constraints.

Keywords

Cite

@article{arxiv.1404.5973,
  title  = {Complex Scalar DM in a B-L Model},
  author = {B. L. Sánchez-Vega and J. C. Montero and E. R. Schmitz},
  journal= {arXiv preprint arXiv:1404.5973},
  year   = {2014}
}

Comments

20 pages, 3 figures

R2 v1 2026-06-22T03:57:25.573Z