Intense Beam of Metastable Muonium for Testing the Standard Model

Precision spectroscopy of the Muonium Lamb shift and fine structure requires a robust source of $2S$ Muonium. To date, the beam-foil technique is the only demonstrated method for creating such a beam in vacuum. Previous experiments using this technique were statistics limited, and new measurements would benefit tremendously from low energy muon ($<20$ keV) sources where the $2S$ production is more efficient. Such a source of low energy $\mu^+$ has only become available at large quantities in recent years at the Low-Energy Muon beamline at the Paul Scherrer Institute. Here we report on the successful creation of an intense, directed beam of metastable Muonium. We find that even though the theoretical Muonium fraction is maximal at low energy ($2-5$ keV), scattering by the foil and transport characteristics of the beamline favor higher energy $\mu^+$ ($7-10$ keV). We estimate that an event detection rate of few per second for a future Lamb shift measurement is feasible, enabling an improvement by a factor $100$ over the previous determinations within days of beam time.