Book contents
- Frontmatter
- Contents
- Group photograph
- List of participants
- Preface
- Reviews
- Observational projects
- Posters
- 29 Towards a helioseismic calibration of the equation of state in the solar convective envelope
- 30 Thermal cyclotron and annihilation radiation in strong magnetic fields
- 31 Modified adiabatic approximation for a hydrogen atom moving in a magnetic field
- 32 Computations of static white dwarf models: A must for asteroseismological studies
- 33 The Chandrasekhar mass of a gravitating electron crystal
- 34 Coulomb corrections in the nuclear statistical equilibrium regime
- 35 Molecular Opacities: Application to the Giant Planets
- 36 On Radiative Transfer Near the Plasma Frequency at Strong Coupling
- 37 Effects of Superfluidity on Spheroidal Oscillations of Neutron Stars
- 38 Magnetic Field Decay in the Non-superfluid Regions of Neutron Star Cores
- 39 On the equation of state in Jovian seismology
- 40 Analysis of the screening formalisms in solar and stellar conditions
- 41 Theoretical Description of the Coulomb Interaction by Padé-Jacobi Approximants
- 42 New Model Sequences from the White Dwarf Evolution Code
33 - The Chandrasekhar mass of a gravitating electron crystal
from Posters
Published online by Cambridge University Press: 07 September 2010
- Frontmatter
- Contents
- Group photograph
- List of participants
- Preface
- Reviews
- Observational projects
- Posters
- 29 Towards a helioseismic calibration of the equation of state in the solar convective envelope
- 30 Thermal cyclotron and annihilation radiation in strong magnetic fields
- 31 Modified adiabatic approximation for a hydrogen atom moving in a magnetic field
- 32 Computations of static white dwarf models: A must for asteroseismological studies
- 33 The Chandrasekhar mass of a gravitating electron crystal
- 34 Coulomb corrections in the nuclear statistical equilibrium regime
- 35 Molecular Opacities: Application to the Giant Planets
- 36 On Radiative Transfer Near the Plasma Frequency at Strong Coupling
- 37 Effects of Superfluidity on Spheroidal Oscillations of Neutron Stars
- 38 Magnetic Field Decay in the Non-superfluid Regions of Neutron Star Cores
- 39 On the equation of state in Jovian seismology
- 40 Analysis of the screening formalisms in solar and stellar conditions
- 41 Theoretical Description of the Coulomb Interaction by Padé-Jacobi Approximants
- 42 New Model Sequences from the White Dwarf Evolution Code
Summary
Abstract
The internal structure of a white dwarf may be changed by a strong magnetic field. A local model of the electrons is constructed within a thermal density matrix formalism, essentially a Heisenberg magnetism model. This results in a matrix Fermi function which is used to construct an isothermal model of the electron crystal. The central density of the crystal is 108kg/m3 independent of the magnetic field within the plasma and therefore lower than the relativistic density, whereas this density is constant until the Fermi momentum xf = 0.3 * me * c. Chandrasekhar masses up to 1.44 * 1.4M0 are possible for polarizations of the plasma zone lower than 0.5, if the temperature is close to the Curie point, whereas the crystal itself destabilizes the white dwarf dependent on temperature.
Introduction
From the theory of magnetic phase transitions of solid state physics (Grosse 1988) it is expected, that the structure of a single white dwarf is changed drastically by a magnetic field. The polarized electrons throughout the star may interact due to a magnetic field. The nonlinear influence of a crystallization transition and the crystal itself may change the mass and radius of a white dwarf. We construct a thermal Heisenberg model of the electrons which results in a Fermi matrix function, which predicts a plasma crystal phase transition. This Fermi function is used within the standard white dwarf theory.
- Type
- Chapter
- Information
- The Equation of State in AstrophysicsIAU Colloquium 147, pp. 565 - 570Publisher: Cambridge University PressPrint publication year: 1994