Dark Forces and Light Dark Matter

TL;DR

This paper explores a dark matter model involving a new gauge boson that explains gamma-ray observations, cosmic ray spectra, and direct detection signals through a unified framework.

Contribution

It introduces a simple model where dark matter interacts via a light gauge boson, fitting multiple astrophysical and experimental data sets.

Findings

Gamma-ray spectrum from Galactic Center fits observations.

Model explains hard electron spectra in Milky Way radio filaments.

Predicted scattering cross section aligns with direct detection signals.

Abstract

We consider a simple class of models in which the dark matter, X, is coupled to a new gauge boson, phi, with a relatively low mass (m_phi \sim 100 MeV-3 GeV). Neither the dark matter nor the new gauge boson have tree-level couplings to the Standard Model. The dark matter in this model annihilates to phi pairs, and for a coupling of g_X \sim 0.06 (m_X/10 GeV)^1/2 yields a thermal relic abundance consistent with the cosmological density of dark matter. The phi's produced in such annihilations decay through a small degree of kinetic mixing with the photon to combinations of Standard Model leptons and mesons. For dark matter with a mass of \sim10 GeV, the shape of the resulting gamma-ray spectrum provides a good fit to that observed from the Galactic Center, and can also provide the very hard electron spectrum required to account for the observed synchrotron emission from the Milky Way's radio filaments. For kinetic mixing near the level naively expected from loop-suppressed operators (epsilon \sim 10^{-4}), the dark matter is predicted to scatter elastically with protons with a cross section consistent with that required to accommodate the signals reported by DAMA/LIBRA, CoGeNT and CRESST-II.