Muonium in Solid Neon with Impurities

Unlike in gaseous neon, where there is virtually no muonium (Mu) formation, a large fraction of the positive muons (µ⁺) stopped in liquid neon (l-Ne) and even more of those stopped in solid neon (s-Ne) form Mu via delayed capture of radiolysis electrons produced in their ionization track. The temperature dependence of this fraction reflects the mobility of those electrons as well as any change in the moderation efficiency of the solid.

The muonium relaxation rate in pure s-Ne is the lowest ever observed; it is probably due to the small fraction of natural neon isotopes possessing a magnetic moment. (The main stable isotope, ²⁰Ne, is spinless.)

A very small amount of H₂ impurity serves to nearly double the Mu relaxation rate; 5 times more H₂ has the same effect. One interpretation is that the H₂ does not itself relax the Mu atoms but rather causes them to become localized by disturbing the lattice and breaking the degeneracy between adjacent interstitial sites. The weak relaxation due to dilute neon moments then acts on the static Mu atoms. If this is true, then the muonium diffusion rate in pure s-Ne must be nearly temperature independent, an unusual conclusion.

Muonium relaxation in impure s-Ne fits best to a gaussian relaxation function (power law = 2), whereas the function in pure neon is halfway between gaussian and lorentzian (power law = 1). This would appear to support the conclusions described above, since static Mu atoms in random local magnetic fields due to a dense, regular array of randomly oriented moments would be expected to exhibit gaussian relaxation and the effect of motion is always to cause a trend toward more lorentzian behaviour. However, the moments in pure Ne are almost certain to form a sparse, random array, which should give a lorentzian relaxation even in the static limit.

The gaussian character of the relaxation is further borne out by measurements in zero and weak longitudinal field (ZF/wLF).

One possible conclusion is that the relaxation in s-Ne is not caused by nuclear moments at all, but rather by a very small departure of the interstitial site from cubic symmetry (possibly due to defects, which would explain its enhancement by H₂ impurities but not the fact that this effect is saturated at 0.04% impurities), which in turn spoils the degeneracy between triplet Mu levels in zero field and causes a minute splitting of the Mu precession frequencies in wTF. In this picture Mu is static in s-Ne at all T.

What do you think? A really good explanation and a suggestion for a definitive experiment will get your name on the paper!

Author: JHB. Figure created 1993. See TRIUMF Expt 599.

Prepared by Jess H. Brewer

Last modified: Mon Dec 1 17:47:47 EST