Abstract
Recently, there has been renewed interest in second sound in superfluid Bose and Fermi gases. By using two-fluid hydrodynamic theory, we review the density response χnn(q, ω) of these systems as a tool to identify second sound in experiments based on density probes. Our work generalizes the well-known studies of the dynamic structure factor S(q, ω) in superfluid 4He in the critical region. We show that, in the unitary limit of uniform superfluid Fermi gases, the relative weight of second versus first sound in the compressibility sum rule is given by the Landau–Placzek ratio for all temperatures below Tc. In contrast to superfluid 4He, ϵLP is much larger in strongly interacting Fermi gases, being already of order unity for T∼0.8Tc, thereby providing promising opportunities to excite second sound with density probes. The relative weights of first and second sound are quite different in S(q, ω) (measured in pulse propagation studies) as compared with Imχnn(q, ω) (measured in two-photon Bragg scattering). We show that first and second sound in S(q, ω) in a strongly interacting Bose-condensed gas are similar to those in a Fermi gas at unitarity. However, in a weakly interacting Bose gas, first and second sound are mainly uncoupled oscillations of the thermal cloud and condensate, respectively, and second sound has most of the spectral weight in S(q, ω). We also discuss the behaviour of the superfluid and normal fluid velocity fields involved in first and second sound.
Highlights
The most dramatic effects related to superfluidity in liquid 4He arise [1] when the dynamics of the two components are described by the two-fluid hydrodynamics first discussed by Landau [2]
The purpose of this paper is to provide a systematic study of the density response function χnn(q, ω) of a uniform superfluid atomic gas in the hydrodynamic regime [11, 12], as described by the non-dissipative Landau two-fluid equations
In B, we provide a detailed analysis of the superfluid and normal fluid velocity fields associated with first and second sound
Summary
The most dramatic effects related to superfluidity in liquid 4He arise [1] when the dynamics of the two components are described by the two-fluid hydrodynamics first discussed by Landau [2]. Recent experimental work on trapped Bose-condensed gases has reported some success, with evidence for a second sound mode in highly elongated (cigar-shaped) traps [4] Another approach to achieving conditions where the Landau two-fluid description is correct has been to consider a Fermi superfluid gas close to unitarity [5], where the s-wave scattering length between Fermi atoms in two different hyperfine states is infinite. The purpose of this paper is to provide a systematic study of the density response function χnn(q, ω) of a uniform superfluid atomic gas in the hydrodynamic regime [11, 12], as described by the non-dissipative Landau two-fluid equations (see sections II and III) In this hydrodynamic region, the related dynamic structure factor is given by S(q, ω) ∝ Imχnn(q, ω)/ω. In B, we provide a detailed analysis of the superfluid and normal fluid velocity fields associated with first and second sound
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