Drell-Yan Production of New Particles at Fixed-Target Experiments: Heavy Neutral Lepton as a Case Study

Abstract

We demonstrate the sensitivity of Drell-Yan production processes from deep inelastic scattering in searches for beyond-the-Standard Model (BSM) physics at fixed-target or beam-bump experiments. We take heavy neutral leptons (HNLs) as a case study, produced from the decay of a light vector boson mediator with mass in the range of 2-20 GeV, which itself is generated via the Drell-Yan process. The produced HNLs subsequently decay into Standard Model final states. We consider several current and future experiments, including SBND, DarkQuest, DUNE Near Detector (ND), and SHiP. Utilizing π0 and e+e- final states from HNL decays, we find that the Drell-Yan mechanism provides important contributions and significantly enhances the HNL search sensitivity, owing to the production of energetic final-state particles that are more readily detectable over the expected backgrounds. We find that at 90\% C.L. sensitivity, for gauge couplings gX 10-2\ (10-3) and kinematically accessible mass range, SBND and DarkQuest can probe the HNL flavor mixing |U| 3× 10-4\ (10-3), whereas DUNE ND and SHiP may extend the sensitivity down to the Type-I Seesaw prediction of |U| 10-5. Finally, for our chosen benchmark |U| = 10-3 outside of the current experimental constraints, with a fixed mass ratio mZ'/mN = 2.1, and working within the U(1)B-L, U(1)B-3Lτ, and U(1)B parameter spaces, we find that both SBND and DarkQuest can probe gX 10-3, DUNE ND can reach gX 10-4, and SHiP can probe down to gX 5× 10-6. Our approach provides a powerful new technique to study HNL production at future fixed-target experiments and can readily be extended to other light BSM particle production within a broader class of dark sector models.