Book contents
- Frontmatter
- Contents
- Preface
- 1 Outline
- 2 Pair correlation function and structure factor of ions
- 3 Thermodynamics
- 4 Electron screening and effective ion-ion interactions
- 5 Interionic forces and structural theories
- 6 Statistical mechanics of inhomogeneous systems and freezing theory
- 7 Electronic and atomic transport
- 8 Hydrodynamic limits of correlation functions and neutron scattering
- 9 Critical behaviour
- 10 Electron states, including critical region
- 11 Magnetism of normal and especially of expanded liquid metals
- 12 Liquid-vapour surface
- 13 Binary liquid-metal alloys
- 14 Two-component theory of pure liquid metals
- 15 Shock-wave studies
- 16 Liquid hydrogen plasmas and constitution of Jupiter
- Appendices
- 2.1 Fluctuation theory derivation of S(0) in terms of compressibility
- 3.1 Percus-Yevick hard sphere solution for direct correlation function
- 3.2 Weeks-Chandler-Andersen (WCA) approximation to structure factor
- 5.1 Pressure dependence of pair function related to three-particle correlations
- 5.2 Conditions to be satisfied by thermodynamically consistent structural theories
- 5.3 Gaussian core model and Kirkwood decoupling of triplet correlations
- 5.4 Specific heats of liquids in terms of higher-order correlation functions
- 5.5 Inversion of measured structure, constrained by pseudopotential theory, to extract ion-ion interaction
- 6.1 Vacancy formation energy evaluated in a hot (model) crystal
- 6.2 Vacancy formation energy related to Debye temperature
- 7.1 Inverse transport theory for noninteracting electrons
- 8.1 Method of fluctuating hydrodynamics
- 8.2 Asymptotic behaviour of other Green-Kubo time correlation functions
- 8.3 Dynamics of S(k, ω) included through self-function Ss(k, ω)
- 8.4 Fourth moment theorem for dynamical structure factor
- 8.5 One-dimensional barrier crossing: Kramers' theory
- 8.6 Mode-coupling and velocity field methods
- 9.1 Ornstein-Zernike treatment of critical correlations
- 9.2 Homogeneity, scaling, and an introduction to renormalization group method
- 9.3 Compressibility ratios and thermal pressure coefficients of simple monatomic liquids from model equations of state
- 9.4 Mode coupling applied to critical behaviour
- 9.5 Proof of Wiedemann-Franz law up to metal-insulator transition for Fermi liquid model
- 10.1 Plasmon properties as function of phenomenological relaxation time
- 11.1 Heavy Fermion theory
- 13.1 Conformal solution theory: thermodynamics and structure
- 13.2 Results for concentration fluctuations from quasi-chemical approximation
- 13.3 Density profiles, direct correlation functions, and surface tension of liquid mixtures
- 13.4 Relation of surface segregation phenomenology to first-principles statistical mechanics
- 13.5 Long-time behaviour of correlation functions in binary alloys
- 13.6 Hydrodynamic correlation functions in a binary alloy
- 13.7 Metallic binary liquid-glass transition
- 13.8 Haeffner effect, electromigration, and thermal transport
- 13.9 Theory of disorder localization of noninteracting electrons
- 14.1 Phonon-plasmon model
- 14.2 Response functions for mass densities
- 14.3 Quantum hydrodynamic limit of two-component theory
- 14.4 Evaluation of transport coefficients
- 14.5 Electron-ion structure factor in a nonequilibrium situation
- 14.6 Relations between long-wavelength limit structure factors in binary metallic alloys
- 16.1 Integral equations for correlations in liquid metals, especially hydrogen
- 16.2 Quantum Monte Carlo calculations of ground state of solid hydrogen
- References
- Index
5.5 - Inversion of measured structure, constrained by pseudopotential theory, to extract ion-ion interaction
Published online by Cambridge University Press: 19 January 2010
Book contents
- Frontmatter
- Contents
- Preface
- 1 Outline
- 2 Pair correlation function and structure factor of ions
- 3 Thermodynamics
- 4 Electron screening and effective ion-ion interactions
- 5 Interionic forces and structural theories
- 6 Statistical mechanics of inhomogeneous systems and freezing theory
- 7 Electronic and atomic transport
- 8 Hydrodynamic limits of correlation functions and neutron scattering
- 9 Critical behaviour
- 10 Electron states, including critical region
- 11 Magnetism of normal and especially of expanded liquid metals
- 12 Liquid-vapour surface
- 13 Binary liquid-metal alloys
- 14 Two-component theory of pure liquid metals
- 15 Shock-wave studies
- 16 Liquid hydrogen plasmas and constitution of Jupiter
- Appendices
- 2.1 Fluctuation theory derivation of S(0) in terms of compressibility
- 3.1 Percus-Yevick hard sphere solution for direct correlation function
- 3.2 Weeks-Chandler-Andersen (WCA) approximation to structure factor
- 5.1 Pressure dependence of pair function related to three-particle correlations
- 5.2 Conditions to be satisfied by thermodynamically consistent structural theories
- 5.3 Gaussian core model and Kirkwood decoupling of triplet correlations
- 5.4 Specific heats of liquids in terms of higher-order correlation functions
- 5.5 Inversion of measured structure, constrained by pseudopotential theory, to extract ion-ion interaction
- 6.1 Vacancy formation energy evaluated in a hot (model) crystal
- 6.2 Vacancy formation energy related to Debye temperature
- 7.1 Inverse transport theory for noninteracting electrons
- 8.1 Method of fluctuating hydrodynamics
- 8.2 Asymptotic behaviour of other Green-Kubo time correlation functions
- 8.3 Dynamics of S(k, ω) included through self-function Ss(k, ω)
- 8.4 Fourth moment theorem for dynamical structure factor
- 8.5 One-dimensional barrier crossing: Kramers' theory
- 8.6 Mode-coupling and velocity field methods
- 9.1 Ornstein-Zernike treatment of critical correlations
- 9.2 Homogeneity, scaling, and an introduction to renormalization group method
- 9.3 Compressibility ratios and thermal pressure coefficients of simple monatomic liquids from model equations of state
- 9.4 Mode coupling applied to critical behaviour
- 9.5 Proof of Wiedemann-Franz law up to metal-insulator transition for Fermi liquid model
- 10.1 Plasmon properties as function of phenomenological relaxation time
- 11.1 Heavy Fermion theory
- 13.1 Conformal solution theory: thermodynamics and structure
- 13.2 Results for concentration fluctuations from quasi-chemical approximation
- 13.3 Density profiles, direct correlation functions, and surface tension of liquid mixtures
- 13.4 Relation of surface segregation phenomenology to first-principles statistical mechanics
- 13.5 Long-time behaviour of correlation functions in binary alloys
- 13.6 Hydrodynamic correlation functions in a binary alloy
- 13.7 Metallic binary liquid-glass transition
- 13.8 Haeffner effect, electromigration, and thermal transport
- 13.9 Theory of disorder localization of noninteracting electrons
- 14.1 Phonon-plasmon model
- 14.2 Response functions for mass densities
- 14.3 Quantum hydrodynamic limit of two-component theory
- 14.4 Evaluation of transport coefficients
- 14.5 Electron-ion structure factor in a nonequilibrium situation
- 14.6 Relations between long-wavelength limit structure factors in binary metallic alloys
- 16.1 Integral equations for correlations in liquid metals, especially hydrogen
- 16.2 Quantum Monte Carlo calculations of ground state of solid hydrogen
- References
- Index
Summary
The use of pair force laws to predict liquid structure is exemplified by the calculations of Swamy (1986) on liquid Na and Al. Using the hypernetted chain ((5.5) with E → c), and also the method of Machin-Woodhead and Chihara (MWC): see Chihara (1984; and other references there), Swamy has explored the results of using various oscillatory potentials to assess the applicability of these integral equations for such force laws. The results thereby obtained have been compared with molecular-dynamics simulation. His studies indicate that the HNC equation underestimates the main peak in S(k). The MWC method seems to give good results for S(k) according to Swamy's studies for shorter-range potentials, but when oscillatory effects are included, it is also deficient near the first peak of S(k).
While difficulties remain with integral-equation treatments of liquid structure for such direct calculations of S(k) from a given potential, it has been known for a long time that the inverse problem of extracting φ(r) from an experimentally determined S(k) (Johnson and March, 1963) is a much more stringent probe of an approximate integral equation. This point has been made quite clear in the work of Levesque, Weis and Reatto (1985; see also Reatto, 1988), which is summarized in Section 5.4.
In this appendix, procedures will be described by which the inversion of liquid structure data can yield pair potentials when these are constrained by requirements imposed by the form of pseudopotential theory, already discussed in Chapters 3 and 4.
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- Liquid MetalsConcepts and Theory, pp. 350 - 352Publisher: Cambridge University PressPrint publication year: 1990