Abstract
We study hidden-sector particles at past (CERN-Hamburg-Amsterdam-Rome-Moscow Collaboration and NuCal), present (NA62, SeaQuest, and DarkQuest), and future (LongQuest) experiments at the high-energy intensity frontier. We focus on exploring the minimal vector portal and the next-to-minimal models in which the productions and decays are decoupled. These next-to-minimal models have mostly been devised to explain experimental anomalies while avoiding existing constraints. We demonstrate that proton fixed-target experiments provide one of the most powerful probes for the MeV to few GeV mass range of these models, using inelastic dark matter (iDM) as an example. We consider an iDM model with a small mass splitting that yields the observed dark matter relic abundance, and a scenario with a sizable mass splitting that can also explain the muon g-2 anomaly. We set strong limits based on the CERN-Hamburg-Amsterdam-Rome-Moscow Collaboration and NuCal experiments, which come close to excluding iDM as a full-abundance thermal dark matter candidate in the MeV to GeV mass range. We also make projections based on NA62, SeaQuest, and DarkQuest and update the constraints of the minimal dark photon parameter space. We find that NuCal sets the only existing constraint in ε∼10^{-8}-10^{-4} regime, reaching ∼800 MeV in dark photon mass due to the resonant enhancement of proton bremsstrahlung production. These studies also motivate LongQuest, a three-stage retooling of the SeaQuest experiment with short (≲5 m), medium (∼5 m), and long (≳35 m) baseline tracking stations and detectors as a multipurpose machine to explore new physics.
Highlights
Introduction.—Given the nonobservation of new physics at the TeV scale and the ever-stronger constraints on weakly interacting massive particle dark matter (DM) [1], many physicists have shifted their attention to the study of dark-sector particles with sub-GeV to few GeV masses
We set strong new constraints on inelastic dark matter (iDM) model parameters in the MeV to GeV regime, based on CHARM and NuCal beam-dump experiments, for both small and sizable iDM mass splitting, ruling out a large portion of the parameter space for iDM to account for the total DM abundance
Inelastic DM: Here, we study iDM composed of a Dirac pair of two-component Weyl spinors, η and ξ, charged under a new Uð1ÞD gauge symmetry
Summary
Introduction.—Given the nonobservation of new physics at the TeV scale and the ever-stronger constraints on weakly interacting massive particle dark matter (DM) [1], many physicists have shifted their attention to the study of dark-sector particles with sub-GeV to few GeV masses. We set strong new constraints on iDM model parameters in the MeV to GeV regime, based on CHARM and NuCal beam-dump experiments, for both small and sizable iDM mass splitting, ruling out a large portion of the parameter space for iDM to account for the total DM abundance.
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