Book contents
- Frontmatter
- Contents
- Group photograph
- List of participants
- Preface
- Reviews
- 1 Equations of state in stellar structure and evolution
- 2 Equation of state of stellar plasmas
- 3 Statistical mechanics of quantum plasmas. Path integral formalism
- 4 Onsager-molecule approach to screening potentials in strongly coupled plasmas
- 5 Astrophysical consequences of the screening of nuclear reactions
- 6 Crystallization of dense binary ionic mixtures. Application to white dwarf cooling theory
- 7 Non crystallized regions of White dwarfs. Thermodynamics. Opacity. Turbulent convection
- 8 White dwarf crystallization
- 9 Gravitational collapse versus thermonuclear explosion of degenerate stellar cores
- 10 Neutron star crusts with magnetic fields
- 11 High pressure experiments for astrophysics
- 12 Equation of state of dense hydrogen and the plasma phase transition; A microscopic calculational model for complex fluids
- 13 The equation of state of fluid hydrogen at high density
- 14 A comparative study of hydrogen equations of state
- 15 Strongly coupled ionic mixtures and the H/He equation of state
- 16 White dwarf seismology: Influence of the constitutive physics on the period spectra
- 17 Helioseismology: the Sun as a strongly-constrained, weakly-coupled plasma
- 18 Transport processes in dense stellar plasmas
- 19 Cataclysmic variables: structure and evolution
- 20 Giant planet, brown dwarf, and low-mass star interiors
- 21 Searches for brown dwarfs
- 22 Jovian seismology
- Observational projects
- Posters
13 - The equation of state of fluid hydrogen at high density
from Reviews
Published online by Cambridge University Press: 07 September 2010
- Frontmatter
- Contents
- Group photograph
- List of participants
- Preface
- Reviews
- 1 Equations of state in stellar structure and evolution
- 2 Equation of state of stellar plasmas
- 3 Statistical mechanics of quantum plasmas. Path integral formalism
- 4 Onsager-molecule approach to screening potentials in strongly coupled plasmas
- 5 Astrophysical consequences of the screening of nuclear reactions
- 6 Crystallization of dense binary ionic mixtures. Application to white dwarf cooling theory
- 7 Non crystallized regions of White dwarfs. Thermodynamics. Opacity. Turbulent convection
- 8 White dwarf crystallization
- 9 Gravitational collapse versus thermonuclear explosion of degenerate stellar cores
- 10 Neutron star crusts with magnetic fields
- 11 High pressure experiments for astrophysics
- 12 Equation of state of dense hydrogen and the plasma phase transition; A microscopic calculational model for complex fluids
- 13 The equation of state of fluid hydrogen at high density
- 14 A comparative study of hydrogen equations of state
- 15 Strongly coupled ionic mixtures and the H/He equation of state
- 16 White dwarf seismology: Influence of the constitutive physics on the period spectra
- 17 Helioseismology: the Sun as a strongly-constrained, weakly-coupled plasma
- 18 Transport processes in dense stellar plasmas
- 19 Cataclysmic variables: structure and evolution
- 20 Giant planet, brown dwarf, and low-mass star interiors
- 21 Searches for brown dwarfs
- 22 Jovian seismology
- Observational projects
- Posters
Summary
Abstract
We present a free energy model for fluid hydrogen at high-density and high-temperature. This model aims at describing pressure dissociation and ionization, which occur in partially ionized plasmas encountered in the interiors of giant planets and low-mass stars. The model describes an interacting mixture of H2,H,H+ and e− in chemical equilibrium. The concentrations of H2+ and H− ions are found to be negligible for equation of state purposes. Our model relies on the so-called chemical picture approach, based on the factorization of the partition function into translational, internal and configurational degrees of freedom. The present model is found to be unstable in the pressure-ionization regime and predicts the existence of a first-order plasma phase transition (PPT) which ends up at a critical point given by Tc = 15300 K, Pc = 0.614 Mbar, and ρc = 0.35 gcm−3. The transition occurs between a weakly ionized phase and a partially ionized (∼ 50%) phase.
Nous présentons un modèle d'énergie libre pour l'hydrogène fluide à haute densité et haute température. Le but de ce modèle est de décrire la dissociation et l'ionisation en pression, telles qu'elles se produisent dans les plasmas partiellement ionisés rencontrés à l'intérieur des planètes géantes et des étoiles de faible masse. Le modèle décrit un fluide en interaction composé de H2,H,H+ et e− en équilibre chimique.
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- Information
- The Equation of State in AstrophysicsIAU Colloquium 147, pp. 287 - 305Publisher: Cambridge University PressPrint publication year: 1994
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