Hydrodynamics of Superfluid Helium below 0.6°K. II. Velocity and Attenuation of Ultrasonic Waves
- 1 November 1973
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 8 (5) , 2629-2639
- https://doi.org/10.1103/physreva.8.2629
Abstract
The attenuation and velocity of an ultrasonic wave in superfluid helium-4 have been calculated for temperatures below 0.6°K. The calculation is based on the kinetic equations given by Khalatnikov. The phonon Boltzmann equation is solved numerically without making simplifying approximations about the form of the collision integral. The theory predicts that the velocity of sound increases with frequency for very low frequencies, passes through a maximum, decreases to a minimum, and finally increases towards a constant value at high frequencies. A simple explanation for this peculiar behavior is given. The theory is in good agreement with the experimental results of Abrahams et al., and Waters et al.Keywords
This publication has 41 references indexed in Scilit:
- On the temperature dependence of the velocity of sound in liquid heliumJournal of Low Temperature Physics, 1970
- Theory of ultrasonic attenuation and second sound in insulatorsSolid State Communications, 1965
- Finite Linewidths and "Forbidden" Three-Phonon InteractionsPhysical Review B, 1965
- Size dependent ultrasonic absorption in superfluid heliumThe European Physical Journal A, 1964
- On the Mutual Interaction of Parallel PhononsProceedings of the Physical Society, 1963
- Ultrasonic Attenuation in Liquid HeliumProgress of Theoretical Physics, 1962
- Sound Absorption in Liquid Helium II,T<0.5°KPhysical Review B, 1962
- Ultrasonic Absorption in Liquid Helium at Temperatures below 0.6°KPhysical Review B, 1962
- Sound Attenuation in Liquid Helium II at Very Low TemperaturesProgress of Theoretical Physics, 1961
- Phonon-Phonon Interaction in Liquid Helium IIProgress of Theoretical Physics, 1961