Effects of 3He Impurity on Solid 4He Studied by Compound Torsional Oscillator

Abstract

Frequency shifts and dissipations of a compound torsional oscillator induced by solid 4He samples containing 3He impurity concentrations (x3 = 0.3, 3, 6, 12 and 25 in units of 10-6) have been measured at two resonant mode frequencies (f1 = 493 and f2 = 1164 Hz) at temperatures (T) between 0.02 and 1.1 K. The fractional frequency shifts of the f1 mode were much smaller than those of the f2 mode. The observed frequency shifts continued to decrease as T was increased above 0.3 K, and the conventional non-classical rotation inertia fraction was not well defined in all samples with x3 ≥ 3 ppm. Temperatures where peaks in dissipation of the f2 mode occurred were higher than those of the f1 mode in all samples. The peak dissipation magnitudes of the f1 mode was greater than those of the f2 mode in all samples. The activation energy and the characteristic time (τ0) were extracted for each sample from an Arrhenius plot between mode frequencies and inverse peak temperatures. The average activation energy among all samples was 430 mK, and τ0 ranged from 2× 10-7 s to 5× 10-5 s in samples with x3 = 0.3 to 25 ppm. The characteristic time increased in proportion to x32/3. Observed temperature dependence of dissipation were consistent with those expected from a simple Debye relaxation model if the dissipation peak magnitude was separately adjusted for each mode. Observed frequency shifts were greater than those expected from the model. The discrepancies between the observed and the model frequency shifts increased at the higher frequency mode.