Title: Calibration Trigger and Beam Monitoring for the Mu2e Experiment by Means of Decay-in-Orbit $$\mu$$

Over the last few decades, more evidence has come out to suggest that lepton flavor may not be conserved, making the study of charged lepton flavor violation all the more important. A promising way to observe this phenomenon is through muon conversion to electron (in the case without neutrinos produced) on Al, as will occur in the Mu2e experiment, which will run over the course of three years, beginning in 2023. A major part of the apparatus is the aluminum muon stopping target, which a beam of muons hits before releasing the products of muon interactions into the tracker and calorimeter. A muon stopped in the stopping target can undergo three different processes: nuclear capture, decay in orbit and electron conversion, the last of which makes up the E=105 MeV signal we are aiming to observe. Many muons, however, are scattered into a proton absorber around this target. Muons scattered in this way eventually get stopped in the absorber and then undergo decay-in-orbit , with ele ctron products that peak in their momentum distribution at about 50 MeV/c, giving a reference peak that can be used to calibrate the tracker momentum response. A track trigger was then developed to select events with these tracks. The muon beam used in the Mu2e experiment, however, due to the magnetic field on the beam line, is tilted slightly downward, such that more particles interact with the lower part of the tracker. For calibration purposes it is preferable to have a homogeneous distribution of electrons in the tracker volume, requiring a pre-scale factor that is dependent upon the azimuthal angle of the trajectory of closest approach of the helix to the solenoidal axis (“phi”). The factor in question was then found by running Monte Carlo simulations of the electrons produced in the muon decay in the proton absorber, overlaid with background particles. In addition to being used as means to calibrate momentum distribution, these electron tracks can be used to monitor the muon beam profile for changes over time.Here, these processes are explained in greater detail, and the result of the expected trigger performance is presented.