Fermion-Portal Dark Matter at a High-Energy Muon Collider

TL;DR

This paper explores fermion-portal dark matter models at a future muon collider, analyzing their detection prospects through prompt and long-lived particle signatures, and developing strategies to distinguish signals from Standard Model backgrounds.

Contribution

It provides the first comprehensive analysis of fermion-portal dark matter at a muon collider, including new search strategies and the impact of muon parton distribution functions.

Findings

Upper bounds on mediator masses from relic abundance calculations

Development of background suppression techniques using kinematic cuts

Identification of unique long-lived particle signatures such as charged tracks and displaced vertices

Abstract

In this work, we provide a comprehensive study of fermion-portal dark matter models in the freeze-in regime at a future muon collider. For different possible non-singlet fermion portals, we calculate the upper bound on the mediator's mass arising from the relic abundance calculation and discuss the reach of a future muon collider in probing their viable parameter space in prompt and long-lived particle search strategies. In particular, we develop rudimentary search strategies in the prompt region and show that cuts on the invariant dilepton or dijet masses, the missing transverse mass $M_{T2}$, pseudorapidity and energy of leptons or jets, and the opening angle between the lepton or the jet pair can be employed to subtract the Standard Model background. In the long-lived particle regime, we discuss the signals of each model and calculate their event counts. In this region, the lepton-(quark-)portal model signal consists of charged tracks ($R$-hadrons) that either decay in the detector to give rise to a displaced lepton (jet) signature, or are detector stable and give rise to heavy stable charged track signals. As a byproduct, a pipeline is developed for including the non-trivial parton distribution function of a muon component inside a muon beam; it is shown that this leads to non-trivial effects on the kinematic distributions and attainable significances. We also highlight phenomenological features of all models unique to a muon collider and hope our results, for this motivated and broad class of dark matter models, inform the design of a future muon collider detector. We also speculate on suggestions for improving the sensitivity of a muon collider detector to long-lived particle signals in fermion-portal models.