Uniform-Density Sphere

Review

In an introductory discussion of the virial equilibrium structure of spherically symmetric configurations — see especially the section titled, Energy Extrema — we deduced that a system's equilibrium radius, $R_{e q}$ , measured relative to a reference length scale, $R_{0}$ , i.e., the dimensionless equilibrium radius,

$χ_{e q} \equiv \frac{R_{e q}}{R_{0}},$

is given by the root(s) of the following equation:

$2 C χ^{- 2} + (1 - δ_{1 γ_{g}}) 3 (γ_{g} - 1) B χ^{3 - 3 γ_{g}} + δ_{1 γ_{g}} B_{I} - A χ^{- 1} - 3 D χ^{3} = 0,$

where the definitions of the various coefficients are,

$A$	$\equiv$	$\frac{3}{5} \frac{G M_{t o t}^{2}}{R_{0}} \cdot 𝔣_{W},$
$B$	$\equiv$	$\frac{K M_{t o t}}{(γ_{g} - 1)} (\frac{3 M_{t o t}}{4 π R_{0}^{3}})^{γ_{g} - 1} \cdot 𝔣_{A} = \frac{{\bar{c_{s}}}^{2} M_{t o t}}{(γ_{g} - 1)} \cdot 𝔣_{A},$
$B_{I}$	$\equiv$	$3 c_{s}^{2} M_{t o t} \cdot 𝔣_{M},$
$C$	$\equiv$	$\frac{5 J^{2}}{4 M_{t o t} R_{0}^{2}} \cdot 𝔣_{T},$
$D$	$\equiv$	$\frac{4}{3} π R_{0}^{3} P_{e} .$

Once the pressure exerted by the external medium ( $P_{e}$ ), and the configuration's mass ( $M_{t o t}$ ), angular momentum ( $J$ ), and specific entropy (via $K$ ) — or, in the isothermal case, sound speed ( $c_{s}$ ) — have been specified, the values of all of the coefficients are known and $χ_{e q}$ can be determined.

Adiabatic Evolution of an Isolated Sphere

Here we seek to determine the equilibrium radius of a non-rotating configuration ( $J = 0$ ) that undergoes adiabatic compression/expansion ( $δ_{1 γ_{g}} = 0$ ) and that is not confined by an external medium ( $P_{e} = 0$ ).

Solution

In this case, the statement of virial equilibrium is simplified considerably. Specifically, $χ_{e q}$ is given by the root(s) of the equation,

$A χ_{e q}^{- 1}$	$=$	$3 (γ_{g} - 1) B χ_{e q}^{3 - 3 γ_{g}}$
$\Rightarrow χ_{e q}^{3 γ_{g} - 4}$	$=$	$\frac{3 (γ_{g} - 1) B}{A}$
	$=$	$[3 K M_{t o t} (\frac{3 M_{t o t}}{4 π R_{0}^{3}})^{γ_{g} - 1} \cdot 𝔣_{A}] [\frac{3}{5} \frac{G M_{t o t}^{2}}{R_{0}} \cdot 𝔣_{W}]^{- 1}$
	$=$	$(\frac{1}{R_{0}})^{3 γ_{g} - 4} [5 (\frac{3}{4 π})^{γ_{g} - 1} (\frac{K}{G}) M^{(γ_{g} - 2)} \cdot \frac{𝔣_{A}}{𝔣_{W}}] .$

In other words,

$R_{e q} = [5 (\frac{3}{4 π})^{γ_{g} - 1} (\frac{K}{G}) M^{(γ_{g} - 2)} \cdot \frac{𝔣_{A}}{𝔣_{W}}]^{1 / (3 γ_{g} - 4)} .$

Comparison with Detailed Force-Balance Model

This derived solution will look more familiar if, instead of $K$ , we express the solution in terms of the central pressure,

$P_{c} = K ρ_{0}^{γ_{g}},$

where, for this uniform-density sphere, $ρ_{0} = 3 M_{t o t} / (4 π R_{e q}^{3})$ . Hence,

$K$

$=$

$P_{c} (\frac{4 π R_{e q}^{3}}{3 M_{t o t}})^{γ_{g}},$

and the solution takes the form,

$R_{e q}^{3 γ_{g} - 4}$	$=$	$5 (\frac{4 π}{3}) (\frac{P_{c} R_{e q}^{3 γ_{g}}}{G M_{t o t}^{2}}) \cdot \frac{𝔣_{A}}{𝔣_{W}}$
$\Rightarrow R_{e q}^{4}$	$=$	$(\frac{3}{20 π}) (\frac{G M_{t o t}^{2}}{P_{c}}) \cdot \frac{𝔣_{W}}{𝔣_{A}} .$

Or, solving for the central pressure,

$P_{c}$

$=$

$(\frac{3}{20 π} \cdot \frac{𝔣_{W}}{𝔣_{A}}) \frac{G M_{t o t}^{2}}{R_{e q}^{4}} .$

This should be compared with our detailed force-balance solution of the interior structure of an isolated, nonrotating, uniform-density sphere, which gives the precise expression,

$P_{c}$

$=$

$(\frac{3}{8 π}) \frac{G M_{t o t}^{2}}{R_{e q}^{4}} .$

The expression for $P_{c}$ derived from our identification of an extremum in the free energy is identical to the expression derived from the more precise, detailed force-balance analysis, except that the leading numerical coefficients differ by a factor of $(5 𝔣_{A} / 2 𝔣_{W})$ .

From a free-energy analysis alone, the best we can do is assume that both structural form factors, $𝔣_{W}$ and $𝔣_{A}$ , are of order unity. But knowing the detailed force-balance solution allows us to evaluate both form factors. From our introductory discussion of the free energy function, their respective definitions are,

$𝔣_{W}$	$\equiv$	$3 \cdot 5 \int_{0}^{1} {\int_{0}^{x} [\frac{ρ (x)}{ρ_{c}}] x^{2} d x} [\frac{ρ (x)}{ρ_{c}}] x d x,$
$𝔣_{A}$	$\equiv$	$3 \int_{0}^{1} [\frac{P (x)}{P_{c}}] x^{2} d x .$

Now, because the configuration under discussion has a uniform density, we should set $ρ (x) / ρ_{c} = 1$ in the definition of $𝔣_{W}$ which, after evaluation of the nested integrals, gives $𝔣_{W} = 1$ . But, instead of being uniform throughout the configuration, in the detailed force-balance model, the pressure drops from the center to the surface according to the relation,

$\frac{P (x)}{P_{c}} = 1 - x^{2} .$

Integrating over this function, in accordance with the definition of $𝔣_{A}$ , gives,

$𝔣_{A}$

$\equiv$

$3 \int_{0}^{1} (1 - x^{2}) x^{2} d x = 3 [\frac{x^{3}}{3} - \frac{x^{5}}{5}]_{0}^{1} = \frac{2}{5} .$

Hence, the ratio,

$\frac{5 𝔣_{A}}{2 𝔣_{W}} = 1,$

which brings into perfect agreement the two separate determinations of the equilibrium expressions for $R_{e q}$ and $P_{c}$ in terms of one another and the total mass.

This demonstrates that the free-energy approach to determining the equilibrium radius of a spherical configuration is only handicapped by its inability to precisely nail down values of the structural form factors. But this is not a severe limitation as the (dimensionless) form factors are generally of order unity. In contrast, the free-energy analysis brings with it a capability to readily evaluate the global stability of equilibrium configurations.

Adiabatic Evolution of Pressure-truncated Sphere

Here we seek to determine the equilibrium radius of a non-rotating configuration ( $J = 0$ ) that undergoes adiabatic compression/expansion ( $δ_{1 γ_{g}} = 0$ ) and that is embedded in a hot, tenuous external medium whose confining pressure, $P_{e}$ , truncates the configuration.

Solution

In this case, virial equilibrium implies that $χ_{e q}$ is given by the root(s) of the equation,

$3 (γ_{g} - 1) B χ^{3 - 3 γ_{g}} - A χ^{- 1} - 3 D χ^{3} = 0 .$

Hence,

$D$	$=$	$(γ_{g} - 1) B χ_{e q}^{- 3 γ_{g}} - \frac{A}{3} χ_{e q}^{- 4}$
$\Rightarrow \frac{4 π}{3} R_{0}^{3} P_{e}$	$=$	$[K M_{t o t} (\frac{3 M_{t o t}}{4 π R_{0}^{3}})^{γ_{g} - 1} \cdot 𝔣_{A}] χ_{e q}^{- 3 γ_{g}} - [\frac{1}{5} \frac{G M_{t o t}^{2}}{R_{0}} \cdot 𝔣_{W}] χ_{e q}^{- 4}$
$\Rightarrow P_{e}$	$=$	$[K (\frac{3 M_{t o t}}{4 π R_{e q}^{3}})^{γ_{g}} \cdot 𝔣_{A}] - [(\frac{3}{20 π}) \frac{G M_{t o t}^{2}}{R_{e q}^{4}} \cdot 𝔣_{W}]$
	$=$	$P_{c} \cdot 𝔣_{A} - (\frac{3}{20 π}) \frac{G M_{t o t}^{2}}{R_{e q}^{4}} \cdot 𝔣_{W},$

where, in the last step as was recognized above, we have set,

$K$

$=$

$P_{c} (\frac{4 π R_{e q}^{3}}{3 M_{t o t}})^{γ_{g}} .$

Hence, for any external pressure, $P_{e} < P_{c}$ , the pressure-confined equilibrium radius is,

$R_{e q}$

$=$

$[(\frac{3}{20 π}) \frac{G M_{t o t}^{2}}{P_{c}} \cdot \frac{𝔣_{W}}{𝔣_{A}} (1 - \frac{P_{e}}{P_{c}} \cdot \frac{1}{𝔣_{A}})^{- 1}]^{1 / 4} .$

Comparison with Detailed Force-Balance Model

It is reasonable to ask how close this virial expression for the equilibrium radius is to the exact result. As before, from a free-energy analysis alone, the best we can do is assume that both structural form factors, $𝔣_{W}$ and $𝔣_{A}$ , are of order unity. But we can do better than this. To begin with, because $ρ$ is uniform throughout the configuration, $𝔣_{W} = 1$ , even though the configuration is truncated by the imposed external pressure. We need to reassess how $𝔣_{A}$ is evaluated, however, because the pressure does not drop to zero at the surface of the configuration.

Going back to our original definition of the thermodynamic energy reservoir for spherically symmetric adiabatic systems,

$𝔚_{A} = \frac{1}{(γ_{g} - 1)} \int_{0}^{R} 4 π r^{2} P d r,$

we begin by normalizing the radial coordinate to $R_{0}$ , the radius of the isolated (i.e., not truncated) sphere, because we know from the detailed force-balanced solution that, structurally, the pressure varies with $r$ inside the configuration as,

$\frac{P (x)}{P_{c}} = 1 - x^{2},$

where, $x \equiv r / R_{0}$ . Integrating only out to the edge of the truncated sphere, which we will identify as $R_{e}$ and, correspondingly,

$x_{e} \equiv \frac{R_{e}}{R_{0}} = (1 - \frac{P_{e}}{P_{c}})^{1 / 2},$

we have,

$𝔚_{A}$	$=$	$\frac{4 π P_{c} R_{0}^{3}}{(γ_{g} - 1)} \int_{0}^{x_{e}} (1 - x^{2}) x^{2} d x$
	$=$	$\frac{4 π P_{c} R_{0}^{3}}{(γ_{g} - 1)} [\frac{x^{3}}{3} - \frac{x^{5}}{5}]_{0}^{x_{e}} = \frac{P_{c}}{(γ_{g} - 1)} (\frac{4 π R_{e}^{3}}{3}) [1 - \frac{3}{5} x_{e}^{2}]$
	$=$	$\frac{M_{t o t}}{(γ_{g} - 1)} (\frac{P_{c}}{ρ_{c}}) [1 - \frac{3}{5} (1 - \frac{P_{e}}{P_{c}})] .$

Hence, in the case of a pressure-truncated, uniform-density sphere, we surmise that the relevant structural form factor is,

$𝔣_{A} = 1 - \frac{3}{5} (1 - \frac{P_{e}}{P_{c}}) = \frac{2}{5} + \frac{3}{5} \frac{P_{e}}{P_{c}} .$

Plugging this expression for $𝔣_{A}$ along with $𝔣_{W} = 1$ into the just-derived virial equilibrium solution gives,

$(\frac{3}{20 π}) \frac{G M_{t o t}^{2}}{R_{e q}^{4}}$	$=$	$P_{c} \cdot [\frac{2}{5} + \frac{3}{5} \frac{P_{e}}{P_{c}}] - P_{e}$
	$=$	$\frac{2}{5} P_{c} (1 - \frac{P_{e}}{P_{c}})$
$\Rightarrow R_{e q}$	$=$	$[(\frac{3}{2^{3} π}) \frac{G M^{2}}{P_{c}} (1 - \frac{P_{e}}{P_{c}})^{- 1}]^{1 / 4} .$

This result exactly matches the solution for the equilibrium radius of a pressure-truncated, uniform-density sphere that has been derived elsewhere.

SSC/VirialEquilibrium/UniformDensity

Contents

Uniform-Density Sphere

Review

Adiabatic Evolution of an Isolated Sphere

Solution

Comparison with Detailed Force-Balance Model

Adiabatic Evolution of Pressure-truncated Sphere

Solution

Comparison with Detailed Force-Balance Model

See Also

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SSC/VirialEquilibrium/UniformDensity

Uniform-Density Sphere

Review

Adiabatic Evolution of an Isolated Sphere

Solution

Comparison with Detailed Force-Balance Model

Adiabatic Evolution of Pressure-truncated Sphere

Solution

Comparison with Detailed Force-Balance Model

See Also

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