Measurement of the Formation Rate of Muonic Hydrogen Molecules

TL;DR

This paper reports a precise measurement of the muonic hydrogen molecule formation rate, _{pp\u03bc}, which is crucial for interpreting muon capture experiments and was achieved using a novel doping method in hydrogen.

Contribution

The study provides the most precise measurement of _{pp\u03bc} to date, reducing uncertainties in muon capture parameters and improving the accuracy of related fundamental physics measurements.

Findings

_{pp\u03bc} = (2.01 .06(stat) .03(sys)) imes 10^6 s^{-1}

Measurement at conditions similar to main data collection minimizes additional uncertainties

Refined _{pp\u03bc} value causes less than 0.1% shift in key muon capture parameters

Abstract

Background: The rate \lambda_pp\mu\ characterizes the formation of pp\mu\ molecules in collisions of muonic p\mu\ atoms with hydrogen. In measurements of the basic weak muon capture reaction on the proton to determine the pseudoscalar coupling g_P, capture occurs from both atomic and molecular states. Thus knowledge of \lambda_pp\mu\ is required for a correct interpretation of these experiments. Purpose: Recently the MuCap experiment has measured the capture rate \Lambda_S from the singlet p\mu\ atom, employing a low density active target to suppress pp\mu\ formation (PRL 110, 12504 (2013)). Nevertheless, given the unprecedented precision of this experiment, the existing experimental knowledge in \lambda_pp\mu\ had to be improved. Method: The MuCap experiment derived the weak capture rate from the muon disappearance rate in ultra-pure hydrogen. By doping the hydrogen with 20 ppm of argon, a competing process to pp\mu\ formation was introduced, which allowed the extraction of \lambda_pp\mu\ from the observed time distribution of decay electrons. Results: The pp\mu\ formation rate was measured as \lambda_pp\mu = (2.01 +- 0.06(stat) +- 0.03(sys)) 10^6 s^-1. This result updates the \lambda_pp\mu\ value used in the above mentioned MuCap publication. Conclusions: The 2.5x higher precision compared to earlier experiments and the fact that the measurement was performed at nearly identical conditions to the main data taking, reduces the uncertainty induced by \lambda_pp\mu\ to a minor contribution to the overall uncertainty of \Lambda_S and g_P, as determined in MuCap. Our final value for \lambda_pp\mu\ shifts \Lambda_S and g_P by less than one tenth of their respective uncertainties compared to our results published earlier.