Preface from the original version of this HyperText Book (H_Book):

November 18, 1994

Much of our present, basic understanding of the structure, stability, and dynamical evolution of individual stars, short-period binary star systems, and the gaseous disks that are associated with numerous types of stellar systems (including galaxies) is derived from an examination of the behavior of a specific set of coupled, partial differential equations. These equations — most of which also are heavily utilized in studies of continuum flows in terrestrial environments — are thought to govern the underlying physics of all macroscopic "fluid" systems in astronomy. Although relatively simple in form, they prove to be very rich in nature... <more>

|   Tiled Menu   |   Tables of Content   |  Banner Video   |  Tohline Home Page   |

Pictorial Table of Contents

• Pictorial Table of Contents

Context

• Principal Governing Equations
  • Continuity Equation
  • Euler Equation
    • Rotating Reference Frame
    • Jay Call's Hybrid Scheme
  • <math>1^\mathrm{st}</math> Law of Thermodynamics
  • Poisson Equation

• Supplemental Relations
  • Total Pressure
    • Quartic Temperature Solution

• Global Energy Considerations

Applications

Spherically Symmetric Configurations

Introduction (Alternate Introduction)

Structure:

Here we show how the set of principal governing equations (PGEs) can be solved to determine the equilibrium structure of spherically symmetric fluid configurations — such as individual, nonrotating stars or protostellar gas clouds. After supplementing the PGEs by specifying an equation of state of the fluid, the system of equations is usually solved by employing one of three techniques to obtain a "detailed force-balanced" model that provides the radius, <math>~R_\mathrm{eq}</math>, of the equilibrium configuration — given its mass, <math>~M</math>, and central pressure, <math>~P_c</math>, for example — as well as details regarding the internal radial profiles of the fluid density and fluid pressure. As our various discussions illustrate, simply varying the power-law index in a polytropic equation of state gives rise to equilibrium configurations that have a wide variety of internal structural profiles.

If one is not particularly concerned about details regarding the distribution of matter within the equilibrium configuration, a good estimate of the size of the equilibrium system can be determined by assuming a uniform-density structure then identifying local extrema in the system's global free energy … <more>

Solution Strategies:	Detailed Force-Balance (Introduction)	Virial Equilibrium (Introduction)
Example Solutions: Uniform-density sphere          Isolated … ✓ ✓      Embedded in an External Medium … ✓ ✓ Polytropes      Isolated … ✓ ✓      Embedded in an External Medium … ✓ ✓   🎦 Isothermal sphere      Isolated … ✓ ✓      Embedded in an External Medium (Bonnor-Ebert Sphere) … ✓ ✓ Zero-temperature White Dwarf — Overview Power-law density distribution — Overview Other Analytically Definable Models ✓   …   BiPolytropes (also referred to as Composite Polytropes) Overview Overview          Core-Envelope Structure with <math>~(n_c,n_e) = (0,0)</math> … ✓ ✓          Core-Envelope Structure with <math>~(n_c,n_e) = (5,1)</math> … ✓ ✓          Core-Envelope Structure with <math>~(n_c,n_e) = (1,5)</math> … ✓   …            Core-Envelope Structure with <math>~(n_c,n_e) = (\tfrac{3}{2},3)</math> … ✓   …   Limiting Masses — Summary Instabilities Associated with Equilibrium Sequence Turning Points Material Underpinning Summary PowerPoint Slides

Stability:

Background: Sound Waves Solution Strategy Assuming Spherical Symmetry: Eulerian Perspective Lagrangian Perturbations Reconciliation	Virial Stability Bipolytrope Generalization
Example Solutions: Uniform-density sphere Polytropes

Dynamics:

Spherical Collapse: Free Fall Homologous Collapse Collapse of Stellar Cores with n = 3 — investigation by Goldreich & Weber (1980, ApJ, 238, 991) Generalization to Arbitrary Polytropic Index

Two-Dimensional Configurations

• Introduction
  • Cylindrical Coordinates
  • Axisymmetric Configurations

Structure:

Solution Strategies Axisymmetric Configurations	Virial Equilibrium
Example Solutions: Maclaurin Spheroids Rotationally Flattened, Isothermal Structures Polytropic Tori: Papaloizou-Pringle (massless) Tori Self-gravitating Tori Infinitesimally Thin, Nonaxisymmetric Disk

Stability:

Dynamics:

Three-Dimensional Configurations

• Introduction
  • Properties of Homogeneous Ellipsoids
  • Fission Hypothesis of Binary Star Formation

Structure:

Solution Strategies

Example Solutions: Ellipsoidal Figures of Equilibrium Compressible Analogs of Riemann Ellipsoids; see also Note to Hirschmann & Neilsen and Suggested Strategy by Joel

Stability:

• Lou & Bai (2011, MNRAS, 415, 925) — 3D perturbations in an isothermal self-similar flow

Dynamics:

Related Projects Underway

• A Template for Gravitational-Wave Signals from Core-Collapse Supernovae

Appendices

• Equations
• Variables
• References
• Ramblings

See Also

• NIST Digital Library of Mathematical Functions; see also the related CUP Publication

© 2014 - 2021 by Joel E. Tohline |   H_Book Home   |   YouTube   | Appendices: | Equations | Variables | References | Ramblings | Images | myphys.lsu | ADS | Recommended citation:   Tohline, Joel E. (2021), The Structure, Stability, & Dynamics of Self-Gravitating Fluids, a (MediaWiki-based) Vistrails.org publication, https://www.vistrails.org/index.php/User:Tohline/citation