Constraining Light Dark Matter with Low-Energy e+e- Colliders
Abstract
We investigate the power of low-energy, high-luminosity electron--positron colliders to probe hidden sectors with a mass below ~10 GeV that couple to Standard Model particles through a light mediator. Such sectors provide well-motivated dark matter candidates, and can give rise to distinctive mono-photon signals at B-factories and similar experiments. We use data from an existing mono-photon search by BaBar to place new constraints on this class of models, and give projections for the sensitivity of a similar search at a future B-factory such as Belle II. We find that the sensitivity of such searches are more powerful than searches at other collider or fixed-target facilities for hidden-sector mediators and particles with masses between a few hundred MeV and 10 GeV. Mediators produced on-shell and decaying invisibly to hidden-sector particles such as dark matter can be probed particularly well. Sensitivity to light dark matter produced through an off-shell mediator is more limited, but may be improved with a better control of backgrounds, allowing background estimation and a search for kinematic edges. We compare our results to existing and future direct detection experiments and show that low-energy colliders provide an indispensable and complementary avenue to search for light dark matter. The implementation of a mono-photon trigger at Belle II would provide an unparalleled window into such light hidden sectors.
Cite
@article{arxiv.1309.5084,
title = {Constraining Light Dark Matter with Low-Energy e+e- Colliders},
author = {Rouven Essig and Jeremy Mardon and Michele Papucci and Tomer Volansky and Yi-Ming Zhong},
journal= {arXiv preprint arXiv:1309.5084},
year = {2015}
}
Comments
16 pages, 10 figures; typos corrected and references added