Stealth decaying spin-1 dark matter
Abstract
We consider models of decaying spin-1 dark matter whose dominant coupling to the standard model sector is through a dark-Higgs Yukawa portal connecting a TeV-scale vector-like lepton to the standard model (right-handed) electron. Below the electron-positron threshold, dark matter has very slow, loop-suppressed decays to photons and (electron) neutrinos, and is stable on cosmological time-scale for sufficiently small gauge coupling values. Its relic abundance is set by in-equilibrium dark lepton decays, through the freeze-in mechanism. We show that this model accommodates the observed dark matter abundance for natural values of its parameters and a dark matter mass in the ~5keV to 1MeV range, while evading constraints from direct detection, indirect detection, stellar cooling and cosmology. We also consider the possibility of a nonzero gauge kinetic mixing with the standard model hypercharge field, which is found to yield a mild impact on the model's phenomenology.
Cite
@article{arxiv.2009.03060,
title = {Stealth decaying spin-1 dark matter},
author = {Cédric Delaunay and Teng Ma and Yotam Soreq},
journal= {arXiv preprint arXiv:2009.03060},
year = {2021}
}
Comments
21p, 3 figures; v2 - added discussion on resonant photon conversion, conclusion unchanged, to be published in JHEP