Dark Glueball Direct Detection

Abstract

We consider glueball dark matter (DM) in a Yang-Mills dark sector confined at D scale and coupled to the Standard Model through electrically and dark-color charged vector-like fermion portals, with the mass scale m. In a simple case with two lightest mass-degenerate vector-like fermions with opposite electric charges the effective amplitudes with one C-odd glueball (oddball) and odd number of photons vanish, rendering the lightest C-odd spin-1 state with mass m a viable DM candidate provided that m 5.5 D. We develop a controlled effective field theory framework with non-perturbative information supported by QCD phenomenology leading to a quantitative prediction for coherent elastic glueball scattering off nuclei. We find a steep scaling of the spin-independent cross section σ SI D2.15 m-8. This implies that the sensitivity of the current and next-generation xenon experiments in the range of σ SI 10-46 - 10-48 cm2 corresponds to m 3-30 GeV, respectively, for D 0.55-5.5 GeV. We provide a minimal UV completion of the portal sector compatible with collider phenomenology. Our results pave a quantitative foundation for testing glueball DM in direct-detection experiments.