1. Introduction
Density fluctuations in a dilute gas in local equilibrium cause light scattering due to Doppler interactions between the incoming photons and the acoustic modes of the fluid. This effect was first predicted by L. Brillouin1 and described theoretically by Landau and Placzek2. The spectrum reflects the dynamic behavior of density fluctuations and constitutes an experimental test of linear irreversible thermodynamics.
The Rayleigh-Brillouin scattering has been studied since the 1960s3-5 for several gases, where the description of light in terms of electomagnetism was described by Rayleig6 and Brillouin explained the scattering process in terms of fluctuations. In this paper we use kinetic theory base on a rough sphere interation model between rotations and translations light scattering, we study the linearized system of transport equations when the state variables are perturbed from their equilibrum values. That is, if X is a state variable one considers X0 as the equilibrium value and δX the fluctuation:
where δp corresponds to the density fluctuations around the equilibrium state p0, δT the temperature fluctuations around T0 and
In the Euler regime, the linearized system of transport equations reads7:
These equations predict the existence of sound waves in the fluid which propagate with speed characteristic speed CT, given by
In Eq. (6), m is the individual mass of the particles present in the system, T is the temperature and k is the Boltzmann constant.
The interaction of light with the waves present in a dilute static fluid is rather difficult to measure8,9. For a given spatial mode k, the specific fluid-photon interaction depends on the density of the fluid. In this context, the Brillouin scattering is far more easy to be detected for high density systems rather than dilute gases. On the other hand, low density fluids are frequent in astrophysical scenarios in which structures may be formed at very long wavelengths10. This motivates the analysis of the conditions for the existence of acoustic waves in dilute fluids.
In the presence of dissipation, Eqs. (3)-(5) must include transport coefficients that take into account viscosity and heat conductivity, these effects may prevent the existence of sound waves in a dilute gas.
The purpose of the present work is to establish a necessary condition that must be satisfied in order to guarantee the existence of complex roots in the dispersion relation corresponding to the linearized transport system. If only real roots are present, no Brillouin doublet can be observed in a given experimental array. To accomplish this task the paper has been divided as follows: In Sec. 2, the dispersion relation that describes the dynamics of the fluctuations present in a simple dissipative fluid is expressed in terms of only one dissipative parameter, the relaxation time ( r . In Sec. 3, the necessary condition for the existence of three real roots of the dispersion relation is established and a numerical example relevant in low density physics is presented. Final remarks are included in Sec. 4.
2. Dispersion relation in the presence of dissipation
The system of equations for a simple dilute gas consisting of hard spheres are obtained introducing Eq. (2) in the set of transport equations for the Navier-Stokes regime (first order in gradients). When the flux is studied in the Euler regime, the dissipative fluxes Π and heat flux
In Eqs. (7) - (8), δΠ corresponds to the stress tensor fluctuations and
and
where σ corresponds to the traceless symmetric part of the velocity gradient, ηs is the shear viscosity and kth the thermal conductivity of the gas.
The introduction of the constitutive equations in the set (7) - (8) leads to
denoting τr the relaxation time of the gas, the transport coefficients in Eqs. (9)-(10) (become
the system of transport equations can be algebraically expressed as
where
and
The system (11) governs the dynamics of the fluctuations of the local thermodynamic variables of the gas. Real values for s in the dispersion relation det(A) = 0 are identified with exponentially decaying modes. The resulting expression reads:
In the next section, a simple geometrical analysis of the dispersion relation is applied in order to establish a necessary condition for the existence of two different complex roots, which in turn correspond to the presence of acoustic waves in the gas.
3. Analysis of the dispersion relation
Defining Eq. (12) as a function of s, the resulting expression reads
the first two derivatives of ƒ(s) read
The inflection point of ƒ(s) is always located at
or
In the case of astrophysical systems such as globular clusters, densities are quite low and the temperatures are well beyond the ionization values. In this kind of systems acoustic waves may appear if the wavenumber q is low enough.
In Fig. 1, the blue line corresponds to the dispersion relation (Eq. (13)) for q = 10-10 1/m, CT = 102 m/s and τr = 109 s. In this case CT qτr = 10 and no acoustic waves are present for this mode. The red curve corresponds to the dispersion relation for the same values of CT and τr, but with q = 10-13 1/m. In this case two complex roots appear, corresponding to acoustic waves of very large wavelengths.
4. Final Remarks
In Ref.12, the authors computed the Rayleigh-Brillouin spectrum for a relativistic simple fluid. In this paper, the same methodology was used for the dispersion relation, where the Rayleigh peak corresponds for the real root and the Brillouin peaks are given by the conjugate roots of Eq. (13).
It is very hard to find in the literature simple examples in which a discussion of the existence of the roots precedes to the pursue of the solutions of the dispersion equation for dilute mixtures. If dissipation is strong enough, it can prevent the formation of acoustic waves. In fact, the ideas contained in this paper lead to the establishment of a cut-off wavelength that depends on the isothermal speed of sound in the gas.
The extension of this criterion in the case of a single self-gravitating fluid can be analyzed through the dispersion relation13:
and its first two derivatives:
It is interesting to notice that the necessary and sufficient condition for the existence of three different real roots reduces to the inequality:
where
The simplified expression for the discriminant of Eq. (21) is given by
Taking the value of the Jeans wavenumber as
and no unstable modes appear at the ordinary critical wavelength.
We consider that this algebraic approach to the analysis of the Brillouin peaks for dilute fluids is promising and useful for students and researchers interested the subject.