Toward a sub-ppm measurement of the Fermi constant

TL;DR

This paper discusses the MuLan experiment's efforts to measure the muon lifetime with sub-ppm precision, aiming to refine the Fermi constant's value and reduce experimental uncertainties significantly.

Contribution

The paper presents advancements in experimental techniques and new data that will enable a measurement of G_F with unprecedented precision, surpassing previous results.

Findings

Intermediate muon lifetime measurement: 2.197013(24) microseconds

Enhanced detector instrumentation and data collection methods

Projected G_F determination with better than one ppm accuracy

Abstract

The Fermi constant, G_F, describes the strength of the weak force and is determined most precisely from the mean life of the positive muon, tau_mu. Advances in theory have reduced the theoretical uncertainty on G_F as calculated from tau_mu to a few tenths of a part per million (ppm). The remaining uncertainty on G_F is entirely experimental, and is dominated by the uncertainty on tau_mu. The MuLan experiment is designed to measure the muon lifetime to part-per-million precision, a better-than twenty-fold improvement over the previous generation of experiments. In 2007, we reported an intermediate result, tau_mu=2.197013(24) microseconds (11 ppm), which is in excellent agreement with the previous world average. This mean life was measured using a pulsed surface muon beam stopped in a ferromagnetic target, surrounded by a symmetric scintillator detector array. Since this intermediate measurement, the detector was instrumented with waveform digitizers, the muon beam rate and beam extinction were increased, and two data sets were acquired on different targets, each containing over 10^12 muon decays. These data will lead to a new determination of G_F to better than a part per million.