Difference between revisions of "User:Tohline/SSC/Synopsis StyleSheet"
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As we have detailed in an [[User:Tohline/SSC/BipolytropeGeneralization#Free_Energy_and_Its_Derivatives|accompanying discussion]], the first derivative of the relevant free-energy expression is, | As we have detailed in an [[User:Tohline/SSC/BipolytropeGeneralization#Free_Energy_and_Its_Derivatives|accompanying discussion]], the first derivative of the relevant free-energy expression is, | ||
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3^2 P_i V_\mathrm{core}(\gamma_c - \gamma_e) | 3^2 P_i V_\mathrm{core}(\gamma_c - \gamma_e) | ||
+ (4-3\gamma_c ) W_\mathrm{core} | + (4-3\gamma_c ) W_\mathrm{core} | ||
+ (4-3\gamma_e)W_\mathrm{env} | + (4-3\gamma_e)W_\mathrm{env} \, . | ||
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! style="text-align:center; background-color:#ffff99;" width="50%" |<b><font color="maroon" size="+1">&# | ! style="text-align:center; background-color:#ffff99;" width="50%" |<b><font color="maroon" size="+1">⑨</font></b> <b>Approximation: Homologous Expansion/Contraction</b> | ||
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<math>~\ | <math>~\biggl( \frac{2\pi}{3}\biggr)\sigma_c^2 \int_0^R r^2 dM_r</math> | ||
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(4- 3\ | (4- 3\gamma_c) W_\mathrm{core}+ (4- 3\gamma_e) W_\mathrm{env}+ 3^2 (\gamma_c - \gamma_e) P_i V_\mathrm{core} \, . | ||
</math> | </math> | ||
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Latest revision as of 23:02, 4 February 2019
Spherically Symmetric Configurations Synopsis (Using Style Sheet)
| Tiled Menu | Tables of Content | Banner Video | Tohline Home Page | |
Structure
Tabular Overview
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Equilibrium Structure | ||||||||||||||||
① Detailed Force Balance | ③ Free-Energy Identification of Equilibria | |||||||||||||||
Given a barotropic equation of state, <math>~P(\rho)</math>, solve the equation of
for the radial density distribution, <math>~\rho(r)</math>. |
The Free-Energy is,
Therefore, also,
Equilibrium configurations exist at extrema of the free-energy function, that is, they are identified by setting <math>~d\mathfrak{G}/dR = 0</math>. Hence, equilibria are defined by the condition,
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② Virial Equilibrium | ||||||||||||||||
Multiply the hydrostatic-balance equation through by <math>~rdV</math> and integrate over the volume:
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Pointers to Relevant Chapters
⓪ Background Material:
· | Principal Governing Equations (PGEs) in most general form being considered throughout this H_Book |
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· | PGEs in a form that is relevant to a study of the Structure, Stability, & Dynamics of spherically symmetric systems |
· | Supplemental relations — see, especially, barotropic equations of state |
① Detailed Force Balance:
· | Derivation of the equation of Hydrostatic Balance, and a description of several standard strategies that are used to determine its solution — see, especially, what we refer to as Technique 1 |
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② Virial Equilibrium:
· | Formal derivation of the multi-dimensional, 2nd-order tensor virial equations |
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· | Scalar Virial Theorem, as appropriate for spherically symmetric configurations |
· | Generalization of scalar virial theorem to include the bounding effects of a hot, tenuous external medium |
Stability
Isolated & Pressure-Truncated Configurations
Stability Analysis: Applicable to Isolated & Pressure-Truncated Configurations | ||||||||||||||||||||||||||||||||||
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④ Perturbation Theory | ⑦ Free-Energy Analysis of Stability | |||||||||||||||||||||||||||||||||
Given the radial profile of the density and pressure in the equilibrium configuration, solve the eigenvalue problem defined by the, LAWE: Linear Adiabatic Wave (or Radial Pulsation) Equation
to find one or more radially dependent, radial-displacement eigenvectors, <math>~x \equiv \delta r/r</math>, along with (the square of) the corresponding oscillation eigenfrequency, <math>~\omega^2</math>. |
The second derivative of the free-energy function is,
Evaluating this second derivative for an equilibrium configuration — that is by calling upon the (virial) equilibrium condition to set the value of the internal energy — we have,
Note the similarity with ⑥.
the conditions for virial equilibrium and stability, may be written respectively as,
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⑤ Variational Principle | ||||||||||||||||||||||||||||||||||
Multiply the LAWE through by <math>~4\pi x dr</math>, and integrate over the volume of the configuration gives the, Governing Variational Relation
Now, by setting <math>~(d\ln x/d\ln r)_{r=R} = -3</math>, we can ensure that the pressure fluctuation is zero and, hence, <math>~P = P_e</math> at the surface, in which case this relation becomes,
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⑥ Approximation: Homologous Expansion/Contraction | ||||||||||||||||||||||||||||||||||
If we guess that radial oscillations about the equilibrium state involve purely homologous expansion/contraction, then the radial-displacement eigenfunction is, <math>~x</math> = constant, and the governing variational relation gives,
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Bipolytropes
Stability Analysis: Applicable to Bipolytropic Configurations | ||||||||||||||||||||||||||||||||||||||||
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⑧ Variational Principle | ⑩ Free-Energy Analysis of Stability | |||||||||||||||||||||||||||||||||||||||
Governing Variational Relation
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As we have detailed in an accompanying discussion, the first derivative of the relevant free-energy expression is,
where,
and the second derivative of that free-energy function is,
Hence, in bipolytropes, the marginally unstable equilibrium configuration (second derivative of free-energy set to zero) will be identified by the model that exhibits the ratio,
See the accompanying discussion. If — based for example on ⑦ — we make the reasonable assumption that, in equilibrium, the statements,
hold separately, then we satisfy the virial equilibrium condition, namely,
and the second derivative of the relevant free-energy function can be rewritten as,
Note the similarity with ⑨ — temporarily, see this discussion. | |||||||||||||||||||||||||||||||||||||||
⑨ Approximation: Homologous Expansion/Contraction | ||||||||||||||||||||||||||||||||||||||||
If we guess that radial oscillations about the equilibrium state involve purely homologous expansion/contraction, then the radial-displacement eigenfunction is, <math>~x</math> = constant, and the governing variational relation gives,
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See Also
© 2014 - 2021 by Joel E. Tohline |