Probing a Heavy Dark Z Boson at Multi-TeV Muon Colliders: Leveraging the Optimized Recoil Mass Technique

Abstract

We investigate the discovery potential of multi-TeV muon colliders for a heavy dark Z boson (Z D) with a mass above 1 TeV through the associated production channel μ+μ- Z Dγ. This process enables precise MZ D reconstruction using the photon recoil mass (m recoil). Focusing on the Z D jjX and Z D e+e- decay modes, we present strategies for achieving high sensitivity to the kinetic mixing parameter at 3, 6, and 10 TeV muon colliders with integrated luminosities of 1, 4, and 10 ab-1 respectively, assuming Z D decays exclusively into Standard Model particles. A key innovation is our optimized implementation of MZ D-dependent cuts on m recoil, which accounts for the energy-dependent detector response. For heavier Z D, the associated photon becomes less energetic, leading to better photon energy resolution and thus enabling more stringent m recoil cuts. This approach enhances sensitivity for heavier Z D. Conversely, for lighter Z D, the lower-energy electron pair from Z D e+e- enables tighter cuts on the invariant mass of the electron pair (mee), providing better sensitivity in the lighter mass regime. Combining these complementary m recoil- and mee-based selections with both jjX and e+e- channels, we achieve sensitivity down to O(10-3) as MZ D approaches s, substantially surpassing the reach of a 100 TeV proton-proton collider. Even if Z D decays into dark-sector particles, the recoil mass method remains effective, establishing muon colliders as powerful facilities for exploring heavy dark sectors.