Limiting Light Dark Matter with Luminous Hadronic Loops

TL;DR

This paper demonstrates that low-energy hadronic loops induce effective dark matter-photon couplings, enabling detection via electron scattering for light dark matter below 100 MeV, which was previously thought undetectable.

Contribution

It reveals a novel mechanism where hadronic loops generate dark matter-photon interactions, impacting direct detection strategies for sub-100 MeV dark matter.

Findings

Hadronic loops induce effective dark matter-photon couplings.

Dark matter-electron scattering can constrain dark matter-proton interactions below 1 MeV.

Current searches can probe lighter dark matter than previously possible.

Abstract

Dark matter is typically assumed not to couple to the photon at tree level. While annihilation to photons through quark loops is often considered in indirect detection searches, such loop-level effects are usually neglected in direct detection, as they are typically subdominant to tree-level dark matter-nucleus scattering. However, when dark matter is lighter than around 100 MeV, it carries so little momentum that it is difficult to detect with nuclear recoils at all. We show that loops of low-energy hadronic states can generate an effective dark matter-photon coupling, and thus lead to scattering with electrons even in the absence of tree-level dark matter-electron scattering. For light mediators, this leads to an effective fractional electric charge which may be very strongly constrained by astrophysical observations. Current and upcoming searches for dark matter-electron scattering can thus set limits on dark matter-proton interactions down to 1 MeV and below.