Spherically Symmetric Configurations Synopsis (Using Style Sheet)

Structure

Tabular Overview

Spherically Symmetric Configurations that undergo Adiabatic Compression/Expansion — adiabatic index,

γ

$d V = 4 π r^{2} d r$	and	$d M_{r} = ρ d V \Rightarrow M_{r} = 4 π \int_{0}^{r} ρ r^{2} d r$
$W_{g r a v}$	$=$	$- \int_{0}^{R} (\frac{G M_{r}}{r}) d M_{r} \propto R^{- 1}$
$U_{i n t}$	$=$	$\frac{1}{(γ - 1)} \int_{0}^{R} 4 π r^{2} P d r \propto R^{3 - 3 γ}$

Equilibrium Structure

① Detailed Force Balance

③ Free-Energy Identification of Equilibria

Given a barotropic equation of state,

P (ρ)

, solve the equation of

Hydrostatic Balance

$\frac{d P}{d r} = - \frac{G M_{r} ρ}{r^{2}}$

for the radial density distribution, $ρ (r)$ .

The Free-Energy is,

$𝔊$	$=$	$W_{g r a v} + U_{i n t} + P_{e} V$
	$=$	$- a (\frac{R}{R_{0}})^{- 1} + b (\frac{R}{R_{0}})^{3 - 3 γ} + c (\frac{R}{R_{0}})^{3} .$

Therefore, also,

$R_{0} \frac{\partial 𝔊}{\partial R}$	$=$	$a (\frac{R}{R_{0}})^{- 2} + (3 - 3 γ) b (\frac{R}{R_{0}})^{2 - 3 γ} + 3 c (\frac{R}{R_{0}})^{2}$
	$=$	$\frac{R_{0}}{R} [- W_{g r a v} - 3 (γ - 1) U_{i n t} + 3 P_{e} V]$

Equilibrium configurations exist at extrema of the free-energy function, that is, they are identified by setting $d 𝔊 / d R = 0$ . Hence, equilibria are defined by the condition,

$0$

$=$

$W_{g r a v} + 3 (γ - 1) U_{i n t} - 3 P_{e} V .$

② Virial Equilibrium

Multiply the hydrostatic-balance equation through by $r d V$ and integrate over the volume:

$0$	$=$	$- \int_{0}^{R} r (\frac{d P}{d r}) d V - \int_{0}^{R} r (\frac{G M_{r} ρ}{r^{2}}) d V$
	$=$	$- \int_{0}^{R} 4 π r^{3} (\frac{d P}{d r}) d r - \int_{0}^{R} (\frac{G M_{r}}{r}) d M_{r}$
	$=$	$- \int_{0}^{R} [\frac{d}{d r} (4 π r^{3} P) - 12 π r^{2} P] d r + W_{g r a v}$
	$=$	$\int_{0}^{R} 3 [4 π r^{2} P] d r - \int_{0}^{R} [d (3 P V)] + W_{g r a v}$
	$=$	$3 (γ - 1) U_{i n t} + W_{g r a v} - [3 P V]_{0}^{R} .$

Pointers to Relevant Chapters

⓪ Background Material:

·	Principal Governing Equations (PGEs) in most general form being considered throughout this H_Book
·	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

② Virial Equilibrium:

·	Formal derivation of the multi-dimensional, 2^nd-order tensor virial equations
·	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

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

$0$	$=$	$\frac{d}{d r} [r^{4} γ P \frac{d x}{d r}] + [ω^{2} ρ r^{4} + (3 γ - 4) r^{3} \frac{d P}{d r}] x$
[P00], Vol. II, §3.7.1, p. 174, Eq. (3.145)

to find one or more radially dependent, radial-displacement eigenvectors, $x \equiv δ r / r$ , along with (the square of) the corresponding oscillation eigenfrequency, $ω^{2}$ .

The second derivative of the free-energy function is,

$R_{0}^{2} \frac{\partial^{2} 𝔊}{\partial R^{2}}$	$=$	$- 2 a (\frac{R}{R_{0}})^{- 3} + (3 - 3 γ) (2 - 3 γ) b (\frac{R}{R_{0}})^{1 - 3 γ} + 6 c (\frac{R}{R_{0}})$
	$=$	$(\frac{R_{0}}{R})^{2} [2 W_{g r a v} - 3 (γ - 1) (2 - 3 γ) U_{i n t} + 6 P_{e} V] .$

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,

$3 (γ - 1) U_{i n t}$	$=$	$3 P_{e} V - W_{g r a v}$
$\Rightarrow R^{2} [\frac{\partial^{2} 𝔊}{\partial R^{2}}]_{e q u i l}$	$=$	$2 W_{g r a v} - (2 - 3 γ) [3 P_{e} V - W_{g r a v}] + 6 P_{e} V$
	$=$	$(4 - 3 γ) W_{g r a v} + 3^{2} γ P_{e} V .$

Note the similarity with ⑥.

Alternatively, recalling that,

$3 (γ - 1) U_{i n t}$

$=$

$2 S_{t h e r m},$

the conditions for virial equilibrium and stability, may be written respectively as,

$3 P_{e} V$	$=$	$2 S_{t h e r m} + W_{g r a v}$
$\Rightarrow R^{2} [\frac{\partial^{2} 𝔊}{\partial R^{2}}]_{e q u i l}$	$=$	$2 W_{g r a v} - 2 (2 - 3 γ) S_{t h e r m} + 2 [2 S_{t h e r m} + W_{g r a v}]$
	$=$	$4 W_{g r a v} + 6 γ S_{t h e r m} .$

⑤ Variational Principle

Multiply the LAWE through by $4 π x d r$ , and integrate over the volume of the configuration gives the,

Governing Variational Relation

$0$	$=$	$\int_{0}^{R} 4 π r^{4} γ P (\frac{d x}{d r})^{2} d r - \int_{0}^{R} 4 π (3 γ - 4) r^{3} x^{2} (\frac{d P}{d r}) d r$
		$- 4 π [r^{4} γ P x (\frac{d x}{d r})]_{0}^{R} - \int_{0}^{R} 4 π ω^{2} ρ r^{4} x^{2} d r .$
	$=$	$\int_{0}^{R} x^{2} (\frac{d \ln x}{d \ln r})^{2} γ 4 π r^{2} P d r - \int_{0}^{R} (3 γ - 4) x^{2} (- \frac{G M_{r}}{r}) 4 π ρ r^{2} d r$
		$+ [γ 4 π r^{3} P x^{2} (- \frac{d \ln x}{d \ln r})]_{0}^{R} - \int_{0}^{R} 4 π ω^{2} ρ r^{4} x^{2} d r .$

Now, by setting $(d \ln x / d \ln r)_{r = R} = - 3$ , we can ensure that the pressure fluctuation is zero and, hence, $P = P_{e}$ at the surface, in which case this relation becomes,

$ω^{2}$

$=$

$\frac{γ (γ - 1) \int_{0}^{R} x^{2} (\frac{d \ln x}{d \ln r})^{2} d U_{i n t} - \int_{0}^{R} (3 γ - 4) x^{2} d W_{g r a v} + 3^{2} γ x^{2} P_{e} V}{\int_{0}^{R} x^{2} r^{2} d M_{r}}$

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, $x$ = constant, and the governing variational relation gives,

$ω^{2} \int_{0}^{R} r^{2} d M_{r}$

$\leq$

$(4 - 3 γ) W_{g r a v} + 3^{2} γ P_{e} V .$

Bipolytropes

Stability Analysis: Applicable to Bipolytropic Configurations

⑧ Variational Principle

⑩ Free-Energy Analysis of Stability

Governing Variational Relation

$(\frac{2 π}{3}) σ_{c}^{2} \int_{0}^{R^{}} (x r^{})^{2} d M_{r}^{*}$	$=$	$γ_{c} (γ_{c} - 1) \int_{0}^{r_{c o r e}^{}} x^{2} (\frac{d \ln x}{d \ln r^{}})^{2} d U_{i n t}^{} - (3 γ_{c} - 4) \int_{0}^{r_{c o r e}^{}} x^{2} d W_{g r a v}^{*}$
		$+ γ_{e} (γ_{e} - 1) \int_{r_{c o r e}^{}}^{R^{}} x^{2} (\frac{d \ln x}{d \ln r^{}})^{2} d U_{i n t}^{} - (3 γ_{e} - 4) \int_{r_{c o r e}^{}}^{R^{}} x^{2} d W_{g r a v}^{*}$
		$+ 3^{2} (γ_{c} - γ_{e}) x_{i}^{2} P_{i}^{} V_{c o r e}^{} .$

As we have detailed in an accompanying discussion, the first derivative of the relevant free-energy expression is,

$R \frac{\partial 𝔊}{\partial R}$

$=$

$2 S_{t o t} + W_{t o t},$

where,

$S_{t o t} \equiv S_{c o r e} + S_{e n v}$

and

$W_{t o t} \equiv W_{c o r e} + W_{e n v};$

and the second derivative of that free-energy function is,

$R^{2} \frac{\partial^{2} 𝔊}{\partial R^{2}}$

$=$

$2 [W_{t o t} + (3 γ_{c} - 2) S_{c o r e} + (3 γ_{e} - 2) S_{e n v}] .$

This stability criterion may be rewritten as,

$[R^{2} \frac{\partial^{2} 𝔊}{\partial R^{2}}]_{e q u i l}$

$=$

$2 [(3 γ_{c} - 4) S_{c o r e} + (3 γ_{e} - 4) S_{e n v}] .$

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,

$\frac{S_{c o r e}}{S_{e n v}}$

$=$

$\frac{(3 γ_{e} - 4)}{(4 - 3 γ_{c})} .$

See the accompanying discussion.

If — based for example on ⑦ — we make the reasonable assumption that, in equilibrium, the statements,

$2 S_{c o r e} = 3 P_{i} V_{c o r e} - W_{c o r e}$

and

$2 S_{e n v} = - 3 P_{i} V_{c o r e} - W_{e n v},$

hold separately, then we satisfy the virial equilibrium condition, namely,

$0$

$=$

$2 S_{t o t} + W_{t o t},$

and the second derivative of the relevant free-energy function can be rewritten as,

$[R^{2} \frac{\partial^{2} 𝔊}{\partial R^{2}}]_{e q u i l}$	$=$	$2 (W_{c o r e} + W_{e n v}) + (3 γ_{c} - 2) (3 P_{i} V_{c o r e} - W_{c o r e})$
		$+ (3 γ_{e} - 2) (- 3 P_{i} V_{c o r e} - W_{e n v})$
	$=$	$3^{2} P_{i} V_{c o r e} (γ_{c} - γ_{e}) + (4 - 3 γ_{c}) W_{c o r e} + (4 - 3 γ_{e}) W_{e n v} .$

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, $x$ = constant, and the governing variational relation gives,

$(\frac{2 π}{3}) σ_{c}^{2} \int_{0}^{R} r^{2} d M_{r}$

$\leq$

$(4 - 3 γ_{c}) W_{c o r e} + (4 - 3 γ_{e}) W_{e n v} + 3^{2} (γ_{c} - γ_{e}) P_{i} V_{c o r e} .$

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Contents

Spherically Symmetric Configurations Synopsis (Using Style Sheet)

Structure

Tabular Overview

Pointers to Relevant Chapters

Stability

Isolated & Pressure-Truncated Configurations

Bipolytropes

See Also

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SSC/SynopsisStyleSheet

Spherically Symmetric Configurations Synopsis (Using Style Sheet)

Structure

Tabular Overview

Pointers to Relevant Chapters

Stability

Isolated & Pressure-Truncated Configurations

Bipolytropes

See Also

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