Donald G. Fleming, Randall J. Mikula,” and David M. Garner Dept. of Chemistry and TRIVMF\ University of British Columbia, Vancouver, B.C., Canada V6T U6
Using the basic muon spin rotation technique, the fractions of energetic positive muons thermalizing in diamagnetic environments (fp) or as the paramagnetic muonium atom (f mu) have been measured in low pressure pure gases (He, Ne, Ar, Kr, Xe, H2, N2, NH3 , and CHt,) as well as in several gas mixtures (Ne/Xe, Ne/Ar, Ne/NHs, Ne/CHi,). In the pure gases, the muonium fractions f mu are generally found to be smaller than expected from analogous proton charge exchange studies, particularly in the molecular gases. This is probably due to hot atom reactions of muonium following the charge exchange regime. Comparisons with muonium formation in condensed matter as well as positronium formation in gases are also presented. In the gas mixtures, the addition of only a few hundred ppm of a dopant gas, which is exothermic for muonium formation (e.g. Xe), gives rise to an f^u characteristic of the pure dopant gas itself, demonstrating the importance of the neutralization process right down to thermal energies. In all cases, the experimental signal amplitudes are found to be strongly pressure dependent, which is interpreted in terms of the time spent by the muon as neutral muonium in the charge exchange regime: tn < 0.2 ns. This time is generally shorter in the case of molecular gases than in rare gases.
EFS Comments: This speaks to the energy transfer process in the LEEF reactor.
