Fourth Frequency Moments Research Articles

Sum rules and atomic correlations in classical liquids

The sixth frequency moment of the spectral functions of both the longitudinal and transverse current correlations along with their self-parts has been derived for a system of particles interacting through a two-body potential. The first two frequency moments of the spectral function of the energy-density fluctuation, and the first four frequency moments of the spectral function of the kinetic-energy-density fluctuation-correlation functions have also been derived. Numerical estimates for the fourth and sixth frequency moments of the spectral function of the longitudinal current correlations have been made for liquid argon. From this some information about the behavior of the contributions of triplet and quadruplet correlation functions to the frequency moments of liquid argon have been obtained. Numerical estimates have also been made for the first four frequency moments of the kinetic-energy-density fluctuation-correlation function in the long-wavelength limit for liquid argon.

Frequency moments and viscosities of liquid aluminium

Numerical results are presented for the second and fourth frequency moments of the spectral functions of both the longitudinal and transverse current correlation functions for liquid aluminium using the interatomic potential and the static pair correlation function obtained by Schiff (1969) from molecular dynamics calculations. A memory function approach is employed to estimate the longitudinal and shear viscosities of aluminium at its melting point. The parameters appearing in the various memory functions are determined from the frequency moments of the correlation functions. The theoretical estimates of the viscosities are in good agreement with the available experimental value.

Collective excitations in classical liquids

A simple modification of the theory of Hubbard and Beeby (1969) for collective motions in classical liquids is proposed. The modified version is based on a generalized mean-field approximation. The mean field is determined using the zeroth-moment relation. The modified version of the theory now exactly satisfies the zeroth, second and fourth frequency moments of the dynamical structure factor. Numerical calculations have been carried out for the spectral function of the longitudinal current correlations for liquid argon in the range of momentum transfer 0.5-6.3 AA-1. A remarkable improvement over the results obtained from the theory of Hubbard and Beeby has been achieved and the results are in overall good agreement with the molecular-dynamics calculations.

Optical modes in binary alloys

Abstract The existence of a high-frequency, long-wavelength mode in a binary alloy is discussed on the basis of the fourth frequency moment of the correlation between concentration fluctuations.

Approximate solutions of the Liouville equation I. A truncation scheme for distribution functions

The Liouville equation is studied in the domain of validity of linear response theory. The approach is to assume a functional form for the N-body distribution which fits classes of initial distributions exactly. This determines all time-dependent, reduced distribution functions. In the first approximation, the deviation from the exact equilibrium function is assumed to be one-body additive in phase space for all times. The one-body function is fixed by the first equation of the time-dependent hierarchy. This leads to Zwanzig's modification of the linearized Vlasov equation. In the second approximation, we include a two-body additive function and use the first two equations of the hierarchy. With the help of exact identities satisfied by the equilibrium correlations one obtains kinetic equations for the singlet and pair distributions in which the potential has been eliminated and only equilibrium correlation functions appear. In the second approximation, the second and fourth frequency moments of the inelastic scattering function are exact. The resulting truncation scheme is meaningful in any order for both strong short-range forces and for plasmas.

Space-Time Correlations in Exchange-Coupled Paramagnets at Elevated Temperatures

The frequency-dependent correlations ${\ensuremath{\Phi}}_{n}(\ensuremath{\omega})\ensuremath{\equiv}{〈{{S}_{0}}^{z}(t){{S}_{n}}^{z}({t}^{\ensuremath{'}})〉}_{(\ensuremath{\omega})}$, $n=0,1,2,3, \mathrm{and} 4$, and their inverse-lattice Fourier transforms $\ensuremath{\Phi}(\mathbf{K},\ensuremath{\omega})$, have recently been exactly calculated by Carboni and Richards for finite linear chains consisting of $N$ ($N=6,7,8,9, \mathrm{and} 10$) spins ($S=\frac{1}{2}$) in contact with a heat bath at temperature $T\ensuremath{\rightarrow}\ensuremath{\infty}$ and interacting via a nearest-neighbor isotropic Heisenberg exchange interaction. Carboni and Richards have used plausible extrapolation procedures to predict the corresponding correlations in the thermodynamic limit $N\ensuremath{\rightarrow}\ensuremath{\infty}$. As the extension of these exact calculations to two and three dimensions is of prohibitive difficulty, we have constructed an alternative theory, based upon a simple two-parameter Gaussian representation of the generalized diffusivity, for calculating these correlations for general spin and the dimensionality. To test the accuracy of this phenomenological theory (which is, however, free of any arbitrariness in the sense that the diffusivity is exactly specified by the second and the fourth frequency moments of the Fourier transform of the frequency-dependent correlation function, which are known at infinite temperature), we first compare our results for ${\ensuremath{\Phi}}_{n}(\ensuremath{\omega})$ with those given by Carboni and Richards for the one-dimensional spin-\textonehalf{} system and find the agreement to be excellent for $n=0$, good for $n=1,2$ and adequate for $n=3,4$. The comparison of the corresponding results for $\ensuremath{\Phi}(\mathbf{K},\ensuremath{\omega})$ reveals the agreement to be quite satisfactory for $|\mathbf{K}|\ensuremath{\lesssim}\frac{1}{2}\ensuremath{\pi}$ but only adequate for the higher-K range, i.e., $\frac{1}{2}\ensuremath{\pi}\ensuremath{\lesssim}\mathbf{K}\ensuremath{\lesssim}\ensuremath{\pi}$. Further support in favor of our phenomenological theory is obtained from a comparison with another set of available exact "computer experiment" results, whereby ${\ensuremath{\Phi}}_{0}(\ensuremath{\omega})$, ${\ensuremath{\Phi}}_{0}(t)$, and ${\ensuremath{\Phi}}_{1}(t)$ are accurately known for a three-dimensional (simple-cubic) lattice of infinite spins, i.e., $S\ensuremath{\rightarrow}\ensuremath{\infty}$. (This is the limit in which the classical spin system studied by Windsor corresponds to the quantum spin system of interest to us.) The agreement of our result with Windsor's is excellent. The salient features of our results are as follows: (i) In two dimensions, the divergence of ${\ensuremath{\Phi}}_{0}(\ensuremath{\omega})$ for $\ensuremath{\omega}\ensuremath{\rightarrow}0$ becomes less sharp and disappears completely in three dimensions. (ii) The cutoff frequency, beyond which ${\ensuremath{\Phi}}_{0}(\ensuremath{\omega})$ is effectively zero, increases with the dimensionality, being in three dimensions about twice what it is in one dimension. (iii) There exists a system of reduced units, i.e., ${{\ensuremath{\Phi}}_{n}}^{\ensuremath{'}}(\ensuremath{\omega})\ensuremath{\rightarrow}{\ensuremath{\Phi}}_{n}(\ensuremath{\omega}){[S(S+1)]}^{\ensuremath{-}1}$, ${I}^{\ensuremath{'}}\ensuremath{\rightarrow}{[S(S+1)]}^{\frac{1}{2}}I$, and ${\ensuremath{\omega}}^{\ensuremath{'}}\ensuremath{\rightarrow}(\frac{\ensuremath{\omega}}{{I}^{\ensuremath{'}}})$, in which the function ${I}^{\ensuremath{'}}{{\ensuremath{\Phi}}_{n}}^{\ensuremath{'}}({\ensuremath{\omega}}^{\ensuremath{'}})$ is approximately the same for all spins, and the accuracy of this law of corresponding states seems to increase with the increase in the dimensionality.

Frequency-Dependent Self-Correlation Function for the Heisenberg Spin System in One Dimension

The exact numerical calculations by Carboni and Richards for ${〈{{S}_{1}}^{z}(t){{S}_{1}}^{z}(0)〉}_{(\ensuremath{\omega})}$ in a one-dimensional Heisenberg system of $S=\frac{1}{2}$ spins at elevated temperatures are compared with the predictions of a simple, two-parameter Gaussian representation of the generalized diffusivity. The parameters of the diffusivity are completely determined by the known second and fourth frequency moments, and the procedure is free of arbitrary parameters. The results of the calculation are found to be in good agreement with Carboni and Richards. The calculation is also carried out for $S>\frac{1}{2}$, and it is found that with the increase in the magnitude of spin, ${〈{{S}_{1}}^{z}(t){{S}_{1}}^{z}(0)〉}_{(\ensuremath{\omega})}$ gradually loses its characteristic hump and approaches a shape roughly similar to the one which would result from the use of an appropriate Lorentzian for the function ${〈{{S}_{f}}^{z}(t){{S}_{g}}^{z}(0)〉}_{(k,\ensuremath{\omega})}$.

Moments of the Momentum Density Correlation Functions in Simple Liquids

The fourth frequency moments of the longitudinal and transverse momentum correlation functions in a simple, classical liquid have been derived. Numerical results in the $k=0$ limit are given for a Lennard-Jones potential.

Sum rule criterion in coherent slow neutron scattering in liquids

Abstract The fourth frequency moment of the dynamic structure factor S (κ, ω) is computed for liquid argon. It is pointed out that two recently proposed phenomenological prescriptions for calculating S (κ, ω) imply certain approximations to this exact result. These are compared and discussed.