Probing Dark Forces and Light Hidden Sectors at Low-Energy e+e- Colliders

TL;DR

This paper explores how low-energy e+e- colliders can detect dark sectors, which may explain certain astrophysical signals and produce distinctive collider events involving dark matter and new gauge bosons.

Contribution

It provides a comprehensive analysis of dark sector production and decay at e+e- colliders, proposing search strategies and connecting collider signals with astrophysical observations.

Findings

Dark sectors can produce high-multiplicity lepton events at colliders.

Existing data may contain thousands of dark-sector events.

Dark-sector states can have measurable decay lifetimes and mass resonances.

Abstract

A dark sector -- a new non-Abelian gauge group Higgsed or confined near the GeV scale -- can be spectacularly probed in low-energy e+e- collisions. A low-mass dark sector can explain the annual modulation signal reported by DAMA/LIBRA and the PAMELA, ATIC, and INTEGRAL observations by generating small mass splittings and new interactions for weak-scale dark matter. Some of these observations may be the first signs of a low-mass dark sector that collider searches can definitively confirm. Production and decay of O(GeV)-mass dark states is mediated by a Higgsed Abelian gauge boson that mixes kinetically with hypercharge. Existing data from BaBar, BELLE, CLEO-c, and KLOE may contain thousands of striking dark-sector events with a high multiplicity of leptons that reconstruct mass resonances and possibly displaced vertices. We discuss the production and decay phenomenology of Higgsed and confined dark sectors and propose e+e- collider search strategies. We also use the DAMA/LIBRA signal to estimate the production cross-sections and decay lifetimes for dark-sector states.