Synthesis of a high intensity, superthermal muonium beam for gravity and laser spectroscopy experiments

TL;DR

This paper reports the creation of a high-brightness, superthermal muonium beam from superfluid helium, enabling advanced gravity and spectroscopy experiments with second-generation leptons.

Contribution

The study introduces a novel method to produce a bright, narrow-velocity muonium beam suitable for gravity tests and high-precision spectroscopy, overcoming previous limitations.

Findings

Achieved a mean velocity of 2180 m/s with a narrow velocity spread.

Produced muonium yields comparable to the best diffuse sources.

Enabled potential for sub-kHz 1S-2S spectroscopy and gravity measurements.

Abstract

The universality of free fall, a cornerstone of Einstein's theory of gravity, has so far only been tested with neutral composite states of first-generation Standard Model (SM) particles, such as atoms or neutrons, and, most recently, antihydrogen. Extending these gravitational measurements to other sectors of the SM requires the formation of neutral bound states using higher-generation, unstable particles. Muonium, the bound state of an antimuon ($\mu^+$) and an electron ($e^-$), offers the possibility to probe gravity with second-generation (anti)leptons, in the absence of the strong interaction. However, the short $\mu^+$ lifetime ($\tau_{\mu}\approx 2.2~\mu$s) and the existing diffuse thermal muonium sources rendered such measurements unfeasible. Here, we report the synthesis of a high-brightness muonium beam, extracted from a thin layer of superfluid helium by exploiting its chemical potential and unique transport properties. The mean longitudinal velocity (${v}\approx 2180~\rm{m/s}$) and narrow distribution (${\Delta v}< 150 ~\rm{m/s}$) of the atoms characterise a superthermal beam, while yields are similar to the highest intensity diffuse sources. This new beam is expected to enable muonium interferometry and a percent-level measurement of its gravitational acceleration, providing the first direct test of the Weak Equivalence Principle with second-generation (anti)matter. Its unprecedented brightness also opens the way to sub-kHz 1S-2S spectroscopy, enabling precise determination of the muon mass and stringent tests of bound-state quantum electrodynamics.