Low-Temperature Mobility of Surface Electrons and Ripplon-Phonon Interaction in Liquid Helium

Abstract

The low-temperature dc mobility of the two-dimensional electron system localized above the surface of superfluid helium is determined by the slowest stage of the longitudinal momentum transfer to the bulk liquid, namely, by the interaction of surface and volume excitations of liquid helium, which rapidly decreases with temperature. Thus, the temperature dependence of the low-frequency mobility is μdc = 8.4x10-11ne T-20/3 cm4 K20/3/(V s), where ne is the surface electron density. The relation T20/3E-3 << 2x10-7 between the pressing electric field (in kV/cm) and temperature (in K) and the value ω < 108 T5 K-5s-1 of the driving-field frequency have been obtained, at which the above effect can be observed. In particular, E = 1 kV/cm corresponds to T < 70 mK and ω/2π < 30 Hz.