Abstract
The dynamic structure function S(k,omega ) informs about the dispersion and damping of excitations. We have recently (Beauvois et al. in Phys Rev B 97:184520, 2018) compared experimental results for S(k,omega ) from high-precision neutron scattering experiments and theoretical results using the “dynamic many-body theory” (DMBT), showing excellent agreement over the whole experimentally accessible pressure regime. This paper focuses on the specific aspect of the propagation of low-energy phonons. We report calculations of the phonon mean-free path and phonon lifetime in liquid ^{4}He as a function of wavelength and pressure. Historically, the question was of interest for experiments of quantum evaporation. More recently, there is interest in the potential use of ^{4}He as a detector for low-energy dark matter (Schulz and Zurek in Phys Rev Lett 117:121302/1, 2016). While the mean-free path of long wavelength phonons is large, phonons of intermediate energy can have a short mean-free path of the order of {upmu }mathrm{m}. Comparison of different levels of theory indicates that reliable predictions of the phonon mean-free path can be made only by using the most advanced many-body method available, namely DMBT.
Highlights
It has been known for a long time [1,2,3,4] that low-energy phonons in liquid 4He display an anomalous dispersion relation which allows these phonons to decay
The values are shifted, but the density dependence is in excellent agreement with that predicted by theory
The dispersion and damping of low-momentum phonons in superfluid helium-4 is of practical interest for cosmological applications in weakly interacting particle detectors to test hypotheses for dark matter
Summary
It has been known for a long time [1,2,3,4] that low-energy phonons in liquid 4He display an anomalous dispersion relation which allows these phonons to decay. Journal of Low Temperature Physics (2019) 197:113–129 phonon dispersion relation for all experimentally accessible densities with unprecedented accuracy. They confirm the finding of earlier work that the phonon dispersion relation is anomalous up to densities of about ρ = 0.0245 Å−3. The investigations are, among others, of interest because multiple scattering in superfluid 4He has been proposed as a detection mechanism for low-mass dark matter [9,10,11,12], among other proposed detectors [13] Such a detector design requires accurate knowledge of the propagation of low-energy phonons within the medium. When the phonon dispersion relation is anomalous, phonons are damped and have a finite mean-free path
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