Probing the dark photon via polarized DIS scattering at the HERA and EIC

TL;DR

This paper proposes using polarized deep inelastic scattering at HERA and EIC to constrain dark photon properties, achieving bounds comparable to existing limits and highlighting the benefits of polarization and high luminosity.

Contribution

It introduces a novel method utilizing polarized DIS to probe dark photons, providing competitive constraints and exploring the synergy between cross section and asymmetry measurements.

Findings

HERA polarized data constrains mixing parameter ε<0.02 for dark photon mass <10 GeV.

EIC with high luminosity and polarization can improve bounds to ε<0.01–0.02.

Polarization enhances sensitivity to dark photon signals.

Abstract

The dark photon is widely predicted in many new physics beyond the Standard Model. In this work, we propose to utilize the polarized lepton cross section in neutral current DIS process at the HERA and upcoming Electron-Ion Collider (EIC) to probe the properties of the dark photon. It shows that we can constrain the mixing parameter $\epsilon<0.02$ when the dark photon mass $m_{A_D}<10 ~{\rm GeV}$ at the HERA with polarized lepton beam and this bound is comparable to the limit from the unpolarized HERA data. With the help of high integrated luminosity and high electron beam polarization of the EIC, the upper limit of the $\epsilon$ could be further improved. Depending on the assumption of the systematic error of the cross section measurements, we obtain $\epsilon<0.01\sim 0.02$ for the mass region $m_{A_D}<10~{\rm GeV}$ under the integrated luminosity of $300~{\rm fb}^{-1}$. We also discuss the complementary roles between the cross section and the single-spin asymmetry measurements in probing the dark photon.