Latest revision as of 13:11, 28 October 2021

Global Energy Considerations

Global Energy Considerations

Preface

The astrophysics community relies heavily on the virial equations — most often in the context of the scalar virial theorem — to ascertain the basic properties of equilibrium systems. As is described below, fundamentally the virial equations are obtained by taking moments of the Euler equation. By examining the balance among various relevant energy reservoirs, the mathematical expression that defines virial equilibrium provides a means by which, for example, the radius of a configuration can be estimated, given a total system mass and mean system temperature. It can also be used to estimate a system's maximum allowed rotation frequency and whether or not the properties of the equilibrium configuration will be significantly modified if the system is embedded in a hot tenuous external medium.

As is also discussed, below, it can be even more informative to examine how a system's global, Gibbs-like free energy, $𝔊$ , varies under contraction or expansion. Extrema in the free energy identify equilibrium configurations, for example. For spherically symmetric systems, in particular, the scalar virial theorem is "derived" by identifying under what conditions $d 𝔊 / d R = 0$ . Furthermore, the sign of the second derivative, $d^{2} 𝔊 / d R^{2}$ , tells whether or not the equilibrium state is stable or unstable. Here we define relevant energy reservoirs that contribute to a system's global free energy. In separate chapters we use the free energy function to help identify the properties of equilibrium systems and to examine their relative stability.

Why Bother?

Excerpts drawn from the introductory chapter (p. 3) of
George W. Collins, II (1978)
The Virial Theorem in Stellar Astrophysics
© Pachart Publishing House

Question: Why bother introducing the virial theorem and its allied free-energy expression, given that the astrophysical systems we are interested in analyzing can be fully described by solutions of the set of Principal Governing Equations?

Answer: The Principal Governing Equations are, in general, non-linear, second-order, vector differential equations which exhibit closed form solutions only in special cases. Although additional cases may be solved numerically, insight into the behavior of systems in general is very difficult to obtain in this manner. The virial theorem and its associated free-energy expression generally deals in scalar quantities and usually is applied on a global scale. This reduction in complexity — from a vector description to a scalar one — frequently enables us to solve the resulting equations in closed form and to ascertain more straightforwardly what physical processes are most responsible for defining properties of the solution.

Caution: We should always keep in mind that this reduction in complexity results in a concomitant loss of information and we cannot expect to obtain as complete a description of a physical system as would be possible from a full solution of the Principal Governing Equations.

Virial Equations (Inertial Frame)

Most of the material presented here has been drawn from Chandrasekhar's Ellipsoidal Figures of Equilibrium — hereafter [EFE] — first published in 1969. Relying heavily on [EFE's] in-depth treatment of the topic, our aim is to highlight key aspects of the tensor-virial equations and to present them in a form that serves as a foundation for our separate discussions of the equilibrium and stability of self-gravitating fluid systems. Strong parallels are drawn between the [EFE] presentation and our own so that it will be relatively straightforward for the reader to consult the [EFE] publication to obtain details of the various derivations. Text that appears in a green font has been drawn verbatim from this reference.

Setting the Stage

[EFE, §8, p. 15] A standard technique for treating the integro-differential equations of mathematical physics is to take the moments of the equations concerned and consider suitably truncated sets of the resulting equations. The virial method … is essentially the method of the moments applied to the solution of hydrodynamical problems in which the gravitational field of the prevailing distribution of matter is taken into account. The virial equations of the various orders are, in fact, no more than the moments of the relevant hydrodynamical equations. In this context, Chandrasekhar's focus is on two of the four principal governing equations that serve as the foundation of our entire H_Book, namely, the

Euler Equation
(Momentum Conservation)

$\frac{d \vec{v}}{d t} = - \frac{1}{ρ} \nabla P - \nabla Φ$

and the

Poisson Equation

$\nabla^{2} Φ = 4 π G ρ$

In [EFE], the Euler equation first appears in §11 (p. 20) as equation (38) and is written as,

$ρ \frac{d u_{i}}{d t}$

$=$

$- \frac{\partial p}{\partial x_{i}} + ρ \frac{\partial 𝔅}{\partial x_{i}},$

and the Poisson equation appears in §10 (p. 20) — specifically, the left-most component of [EFE's] equation (37) — as,

$\nabla^{2} 𝔅$

$=$

$- 4 π G ρ .$

It is clear, therefore, that Chandrasekhar uses the variable $\vec{u}$ instead of $\vec{v}$ to represent the inertial velocity field. More importantly, he adopts a different variable name and a different sign convention to represent the gravitational potential, specifically,

$- Φ = 𝔅$

$=$

$G \int_{V} \frac{ρ ({\vec{x}}^{^{'}})}{| \vec{x} - {\vec{x}}^{^{'}} |} d^{3} x^{'} .$

Hence, care must be taken to ensure that the signs on various mathematical terms are internally consistent when mapping derivations and resulting expressions from [EFE] into this H_Book.

First-Order Virial Equations

[EFE, §11(a), p. 21] The [virial] equations of the first order are obtained by simply integrating [the Euler equation] over the instantaneous volume, $V$ , occupied by the fluid. Specifically, using our H_Book variable notation,

$\int_{V} ρ \frac{d v_{i}}{d t} d^{3} x$

$=$

$- \int_{V} \frac{\partial P}{\partial x_{i}} d^{3} x - \int_{V} ρ \frac{\partial Φ}{\partial x_{i}} d^{3} x,$

leads to (see [EFE] for details),

$\frac{d^{2} I_{i}}{d t^{2}}$

$=$

$0,$

where the moments of inertia about the three separate principal axes $(i = 1, 2, 3)$ are defined by the expressions,

$I_{i}$

$\equiv$

$\int_{V} ρ x_{i} d^{3} x .$

Thus, the first-order virial equation(s) expresses the uniform motion of the center of mass of the system.

Second-Order Tensor Virial Equations

In discussing the origin of the second-order (tensor) virial equation, [EFE] will continue to serve as our primary reference. However, in §4.3 of their widely referenced textbook titled, "Galactic Dyamics," Binney & Tremaine (1987) — hereafter [BT87] — also present a detailed derivation of the second-order virial equation, which they refer to as the tensor virial theorem. Because their presentation is set in the context of discussions of the structure of stellar dynamic systems, the [BT87] derivation fundamentally originates from the collisionless Boltzmann equation. In what follows we will identify where various key equations appear in [BT87], as well as in [EFE], because it can sometimes be useful to compare derivations made from the stellar-dynamic versus the fluid-dynamic perspective.

Derivation

[EFE, §11(b), p. 22] The second-order (tensor) virial equations are obtained by multiplying [the Euler equation] by $x_{j}$ and integrating over the volume, $V$ . Specifically, again using our H_Book variable notation,

$\int_{V} ρ \frac{d v_{i}}{d t} x_{j} d^{3} x$	$=$	$- \int_{V} x_{j} \frac{\partial P}{\partial x_{i}} d^{3} x - \int_{V} ρ x_{j} \frac{\partial Φ}{\partial x_{i}} d^{3} x,$
[BT87], p. 211, Eq. (4-72)

or, separating the term on the left-hand side into two physically distinguishable components — see equation 44 of [EFE] — this can be rewritten as,

$\frac{d}{d t} \int_{V} ρ v_{i} x_{j} d^{3} x - 2 𝔗_{i j}$	$=$	$δ_{i j} Π + 𝔚_{i j},$
[EFE], p. 22, Eq. (47)

where, by definition,

						References
$𝔗_{i j}$	$\equiv$	$\frac{1}{2} \int_{V} ρ v_{i} v_{j} d^{3} x$	…	is the (ordered) kinetic energy tensor	…	[EFE], p. 17, Eq. (9) [BT87], p. 212, Eq. (4-74b)
$Π$	$\equiv$	$\int_{V} P d^{3} x$	…	is ⅔ of the total thermal (i.e., random kinetic) energy	…	[EFE], p. 16, Eq. (7) [BT87], p. 212, Eq. (4-74b)
$𝔚_{i j}$	$\equiv$	$\frac{1}{2} \int_{V} ρ Φ_{i j} d^{3} x$			…	[EFE], p. 17, Eq. (15) [BT87], p. 68, Eq. (2-126)
	$=$	$- \int_{V} ρ x_{i} \frac{\partial Φ}{\partial x_{j}} d^{3} x$	…	is the gravitational potential energy tensor	…	[EFE], p. 18, Eq. (18) [BT87], p. 67, Eq. (2-123)

Note that, in the definition of the gravitational potential energy tensor, Chandrasekhar has introduced a tensor generalization of the gravitational potential [see his Eq. (14), p. 17], namely,

$- Φ_{i j} = 𝔅_{i j}$

$=$

$G \int_{V} ρ ({\vec{x}}^{'}) \frac{(x_{i} - x_{i}^{'}) (x_{j} - x_{j}^{'})}{| \vec{x} - {\vec{x}}^{^{'}} |^{3}} d^{3} x^{'};$

this same potential energy tensor appears explicitly as part of the expression for $𝔚_{i j}$ that is presented as Equation (2-126), on p. 67 of [BT87].

The antisymmetric part of this tensor expression gives (see [EFE] for details),

$\frac{d}{d t} \int_{V} ρ (v_{i} x_{j} - v_{j} x_{i}) d^{3} x$

$=$

$0,$

which expresses simply the conservation of the angular momentum of the system. The symmetric part of the tensor expression gives what is generally referred to as (see [EFE] for details) the,

Tensor Virial Equation

$\frac{1}{2} \frac{d^{2} I_{i j}}{d t^{2}}$	$=$	$2 𝔗_{i j} + 𝔚_{i j} + δ_{i j} Π,$
[EFE], p. 23, Eq. (51) [BT87], p. 213, Eq. (4-78)

where,

						References
$I_{i j}$	$\equiv$	$\int_{V} ρ x_{i} x_{j} d^{3} x$	…	is the moment of inertia tensor	…	[EFE], p. 16, Eq. (4) [BT87], p. 212, Eq. (4-76)

Steady State (Virial Equilibrium)

[EFE §11(b), p. 22] Under conditions of a stationary state, [the tensor virial equation] gives,

$2 𝔗_{i j} + 𝔚_{i j}$

$=$

$- δ_{i j} Π .$

[This] provides six integral relations which must obtain whenever the conditions are stationary.

Scalar Virial Theorem

Scalar Virial Theorem

Standard Presentation [the Virial of Clausius (1870)]

The trace of the tensor virial equation (TVE), which is obtained by identifying the trace of each term in the TVE, produces the scalar virial equation, which is widely referenced and used by the astrophysics community. More specifically, setting,

				Description		[EFE] Reference
$I = \sum_{i = 1, 3} I_{i i}$	$=$	$\int_{V} ρ (\vec{x}) \| \vec{x} \|^{2} d^{3} x$	=	scalar moment of inertia	…	[Eqs. (3) & (5), p. 16]
$T_{k i n} = \sum_{i = 1, 3} 𝔗_{i i}$	$=$	$\frac{1}{2} \int_{V} ρ \| \vec{v} \|^{2} d^{3} x$	=	total (ordered) kinetic energy	…	[Eq. (8), p. 16]
$W_{g r a v} = \sum_{i = 1, 3} 𝔚_{i i}$	$\equiv$	$- \int_{V} ρ x_{i} \frac{\partial Φ}{\partial x_{i}} d^{3} x$	=	gravitational potential energy	…	[Eq. (18), p. 18]
$S_{t h e r m} = \frac{1}{2} \sum_{i = 1, 3} δ_{i i} Π$	$=$	$\frac{3}{2} \int_{V} P d^{3} x$	=	total thermal (random kinetic) energy	…	[Eq. (7), p. 16]

the scalar virial equation is,

$\frac{1}{2} \frac{d^{2} I}{d t^{2}}$

$=$

$2 (T_{k i n} + S_{t h e r m}) + W_{g r a v};$

and, for a stationary state, we have the equilibrium condition that is broadly referred to as the,

Scalar Virial Theorm

$2 (T_{k i n} + S_{t h e r m}) + W_{g r a v}$	$=$	$0 .$
[BT87], p. 213, Eq. (4-79)

(In a footnote to their Equation 4-79, [BT87] point out that the scalar virial theorem was first proved by R. Clausius in 1870; see various links to this work under our "Related Discussions" subsection, below.)

Generalization

Chapter 24 in Volume II (Gas Dynamics) of [Shu92] presents a generalization of the scalar virial theorem that includes the effects of (a) a magnetic field that threads through a self-gravitating fluid system, and (b) an imposed surface pressure, $P_{e}$ , when the configuration is embedded in a hot, tenuous external medium. Text that appears in an orange font in the following paragraph has been drawn verbatim from this reference.

[Shu92] begins by adding a term to the Euler equation that accounts for the Maxwell stress tensor, $T_{i k}$ , associated with the ambient magnetic field, $\vec{B}$ , where,

$T_{i k} = \frac{B_{i} B_{k}}{4 π} - \frac{| \vec{B} |^{2}}{8 π} δ_{i k} .$

[Shu92], Vol. II, p. 329, Eq. (24.3)

Drawing from Equation (24.1), the associated modified Euler equation is,

$ρ \frac{d v_{i}}{d t}$

$=$

$- \frac{\partial P}{\partial x_{i}} - ρ \frac{\partial Φ}{\partial x_{i}} + \frac{\partial T_{i k}}{\partial x_{k}} .$

[Shu92, Vol. II, pp. 329-330] If we were to multiply [this modified Euler equation] by $x_{m}$ and integrate over volume $V$ , we would get the [appropriately modified] tensor virial theorem, the off-diagonal elements of which carry information concerning angular-momentum conservation (see [EFE] for an exposition). [Here] we shall be more interested in the trace of the tensor equation, which we may derive by simply multiplying [the modified Euler equation] by $x_{i}$ (with an implicit summation over repeated indices) and integrating over $V$ . The resulting relation governing the equilibrium of stationary states (see [Shu92] for derivation details), as we shall reference it, is the

Generalized Scalar Virial Theorem

$2 (T_{k i n} + S_{t h e r m}) + W_{g r a v} + ℳ$	$=$	$P_{e} \oint \vec{x} \cdot \hat{n} d A - \oint \vec{x} \cdot \vec{T} \hat{n} d A,$
[Shu92], Vol. II, p. 331, Eq. (24.12)

where $ℳ$ equals the magnetic energy contained in volume $V$ ,

$ℳ \equiv \int_{V} \frac{| \vec{B} |^{2}}{8 π} d^{3} x .$

[ST83], p. 165, Eq. (7.1.18)
[Shu92], Vol. II, p. 330, Eq. (24.9)

[It should be noted that 📚 S. Chandrasekhar & E. Fermi (1953, ApJ, Vol. 118, pp. 116 - 141) and 📚 L. Mestel & L. Spitzer, Jr. (1956, MNRAS, Vol. 116, pp. 503 - 514) provide early discussions of virial equilibrium conditions that take into account the energy associated with a magnetic field.]

Virial Equations (Rotating Frame)

As we have explained elsewhere, when examining the equilibrium, stability, and dynamical behavior of configurations that are rotating with angular velocity, ${\vec{Ω}}_{f}$ , it is useful to reference the

Lagrangian Representation
of the Euler Equation
as viewed from a Rotating Reference Frame

$[\frac{d \vec{v}}{d t}]_{r o t} = - \frac{1}{ρ} \nabla P - \nabla Φ - 2 {\vec{Ω}}_{f} \times {\vec{v}}_{r o t} - {\vec{Ω}}_{f} \times ({\vec{Ω}}_{f} \times \vec{x}) .$

Chandrasekhar also adopts this tactic. In [EFE], the equivalent expression first appears in §12 as equation (62) and has the form,

$ρ \frac{d u_{i}}{d t}$

$=$

$- \frac{\partial p}{\partial x_{i}} + ρ \frac{\partial 𝔅}{\partial x_{i}} + 2 ρ ϵ_{i ℓ m} u_{ℓ} Ω_{m} + \frac{1}{2} ρ \frac{\partial}{\partial x_{i}} | \vec{Ω} \times \vec{x} |^{2},$

where, as noted in [EFE §12, p. 25], the terms $| \vec{Ω} \times \vec{x} |^{2} / 2$ and $2 \vec{u} \times \vec{Ω}$ represent the centrifugal potential and the Coriolis acceleration, respectively — also see our related discussion of the centrifugal and Coriolis accelerations. As Chandrasekhar details, the Coriolis and centrifugal contributions introduce additional terms to the second-order virial, as follows:

$\frac{d}{d t} \int_{V} ρ v_{i} x_{j} d^{3} x$	$=$	$2 𝔗_{i j} + δ_{i j} Π + 𝔚_{i j}$
		$+ 2 ϵ_{i ℓ m} Ω_{m} \int_{V} ρ v_{ℓ} x_{j} d^{3} x + Ω^{2} I_{i j} - Ω_{i} Ω_{k} I_{k j} .$
[EFE], § 11a, p. 25, Eq. (63) and Epilogue, p. 244, Eq. (1)

In his discussion of the Oscillation and Collapse of Interstellar Clouds, 📚 S. V. Weber (1976, ApJ, Vol. 208, pp. 113 - 126) begins with this form of the second-order virial, but adds to it a contribution due to pressure-confinement by an external medium, as introduced above in the context of Shu's generalization. Specifically, Weber opens up his discussion with the following form of the tensor virial equations:

$\frac{d L_{i j}}{d t}$	$=$	$2 𝔗_{i j} + δ_{i j} Π + 𝔚_{i j}$
		$+ 2 ϵ_{i ℓ m} Ω_{m} L_{ℓ j} + I_{j m} (\| \vec{Ω} \|^{2} δ_{i m} - Ω_{i} Ω_{m}) - \oint P_{e} x_{j} n_{i} d S,$
📚 Weber (1976), Eq. (1)

where,

$L_{i j}$

$\equiv$

$\int_{V} ρ v_{i} x_{j} d^{3} x .$

Free Energy Expression

Associated with any isolated, self-gravitating, gaseous configuration we can identify a total Gibbs-like free energy, $𝔊$ , given by the sum of the relevant contributions to the total energy of the configuration,

$𝔊 = W_{g r a v} + 𝔖_{t h e r m} + T_{k i n} + P_{e} V + \dots$

Here, we have explicitly included the gravitational potential energy, $W_{g r a v}$ , the ordered kinetic energy, $T_{k i n}$ , a term that accounts for surface effects if the configuration of volume $V$ is embedded in an external medium of pressure $P_{e}$ , and $𝔖_{t h e r m}$ , the reservoir of thermodynamic energy that is available to perform work as the system expands or contracts. Our above discussion of the scalar virial theorem provides mathematical definitions of each of these energy terms, except for $𝔖_{t h e r m}$ , which we discuss now.

Reservoir of Thermodynamic Energy

$𝔖_{t h e r m}$ derives from the differential, "PdV" work that is often discussed in the context of thermodynamic systems. It should be made clear that, here, "dV" refers to the differential volume per unit mass, so it should be written as " $d (ρ^{- 1})$ ", to be consistent with the notation used throughout this H_Book. Therefore, the differential thermodynamic work is,

$d 𝔴 = P d (1 / ρ) = - (\frac{P}{ρ^{2}}) d ρ .$

After an evolutionary equation of state has been adopted, this differential relationship can be integrated to give an expression for the energy per unit mass, $𝔴$ , that is potentially available for work. Then we define the thermodynamic energy reservoir as,

$𝔖_{t h e r m} \equiv - \int 𝔴 d m .$

Isothermal Systems

If each element of gas maintains its temperature when the system undergoes compression or expansion — that is, if the compression/expansion is isothermal — then, the relevant evolutionary equation of state is,

$P = c_{s}^{2} ρ,$

where the constant, $c_{s}$ , is the isothermal sound speed. In this case, the expression for the differential thermodynamic work becomes,

$d 𝔴 = - (\frac{c_{s}^{2}}{ρ}) d ρ = - c_{s}^{2} d \ln ρ .$

Hence, to within an additive constant, we have,

$𝔴 = - c_{s}^{2} \ln (\frac{ρ}{ρ_{0}}),$

where, $ρ_{0}$ is a (as yet unspecified) reference density, and integration throughout the configuration gives (for the isothermal case),

$𝔖_{t h e r m} = + \int c_{s}^{2} \ln (\frac{ρ}{ρ_{0}}) d m .$

Adiabatic Systems

If, upon compression or expansion, the gaseous configuration evolves adiabatically, the pressure will vary with density as,

$P = K ρ^{γ_{g}},$

where, $K$ specifies the specific entropy of the gas and $γ_{g}$ is the ratio of specific heats that is relevant to the phase of compression/expansion. In this case, the expression for the differential thermodynamic work becomes,

$d 𝔴 = - K ρ^{γ_{g} - 2} d ρ = - \frac{K}{(γ_{g} - 1)} d ρ^{γ_{g} - 1} .$

Hence, to within an additive constant, we have,

$𝔴 = - \frac{1}{(γ_{g} - 1)} (\frac{P}{ρ}),$

and integration throughout the configuration gives (for the adiabatic case),

$𝔖_{t h e r m} = + \int \frac{1}{(γ_{g} - 1)} (\frac{P}{ρ}) d m = \frac{2}{3 (γ_{g} - 1)} \int \frac{3}{2} (\frac{P}{ρ}) d m = \frac{2}{3 (γ_{g} - 1)} S_{t h e r m},$

where, as introduced in our above discussion of the scalar virial theorem, $S_{t h e r m}$ is the system's total thermal (i.e., random kinetic) energy.

Relationship to the System's Internal Energy

It is instructive to tie this introductory material to the classic discussion of thermodynamic systems, which relates a change in the system's internal energy per unit mass, $Δ u_{i n t}$ , to the differential work, $Δ 𝔴$ , via the expression,

$Δ u_{i n t} = Δ Q - Δ 𝔴,$

where, $Δ Q$ is the change in heat content of the system.

Isothermal Evolutions: Because the internal energy is only a function of the temperature, we can set $Δ u_{i n t} = 0$ for expansions or contractions that occur isothermally. Hence, for isothermal evolutions the change in heat content can immediately be deduced from the expression derived for the differential work; specifically, $Δ Q = Δ 𝔴$ .

Adiabatic Evolutions: By definition, $Δ Q = 0$ for adiabatic evolutions, in which case we find $Δ u_{i n t} = - Δ 𝔴$ . The definition of the thermodynamic energy reservoir can therefore be rewritten as,

$𝔖_{t h e r m} = - \int 𝔴 d m = + \int u_{i n t} d m = U_{i n t} .$

Quite generally, then — in sync with the above derivation — we can replace $𝔖_{t h e r m}$ by,

$U_{i n t} = \frac{2}{3 (γ_{g} - 1)} S_{t h e r m},$

in the expression for the free energy when analyzing adiabatic evolutions.

Illustration

As is derived in an accompanying discussion, for a uniform-density, uniformly rotating, spherically symmetric configuration of mass $M$ and radius $R$ ,

$W_{g r a v}$	$=$	$- \frac{3}{5} \frac{G M^{2}}{R_{0}} (\frac{R}{R_{0}})^{- 1},$
$T_{k i n}$	$=$	$\frac{5}{4} \frac{J^{2}}{M R_{0}^{2}} (\frac{R}{R_{0}})^{- 2},$
$V$	$=$	$\frac{4}{3} π R_{0}^{3} (\frac{R}{R_{0}})^{3},$

where, $J$ is the system's total angular momentum and $R_{0}$ is a reference length scale.

Adiabatic Systems: If, upon compression or expansion, the gaseous configuration behaves adiabatically, the reservoir of thermodynamic energy is,

$𝔖_{t h e r m} = U_{i n t} = \frac{M K ρ^{γ_{g} - 1}}{(γ_{g} - 1)} = \frac{M K}{(γ_{g} - 1)} (\frac{3 M}{4 π R_{0}^{3}})^{γ_{g} - 1} (\frac{R}{R_{0}})^{- 3 (γ_{g} - 1)} .$

Hence, the adiabatic free energy can be written as,

$𝔊 = - A (\frac{R}{R_{0}})^{- 1} + B (\frac{R}{R_{0}})^{- 3 (γ_{g} - 1)} + C (\frac{R}{R_{0}})^{- 2} + D (\frac{R}{R_{0}})^{3},$

where,

$A$	$\equiv$	$\frac{3}{5} \frac{G M^{2}}{R_{0}},$
$B$	$\equiv$	$[\frac{K}{(γ_{g} - 1)} (\frac{3}{4 π R_{0}^{3}})^{γ_{g} - 1}] M^{γ_{g}},$
$C$	$\equiv$	$\frac{5 J^{2}}{4 M R_{0}^{2}},$
$D$	$\equiv$	$\frac{4}{3} π R_{0}^{3} P_{e} .$

Isothermal Systems: If, upon compression or expansion, the configuration remains isothermal — also see Appendix A of 📚 S. W. Stahler (1983, ApJ, Vol. 268, pp. 165 - 184) — the reservoir of thermal energy is,

$𝔖_{t h e r m}$

$=$

$M c_{s}^{2} \ln (\frac{ρ}{ρ_{0}}) = - 3 M c_{s}^{2} (\frac{R}{R_{0}}) .$

Hence, the isothermal free energy can be written as,

$𝔊 = - A (\frac{R}{R_{0}})^{- 1} - B_{I} \ln (\frac{R}{R_{0}}) + C (\frac{R}{R_{0}})^{- 2} + D (\frac{R}{R_{0}})^{3},$

where, aside from the coefficient definitions provided above in association with the adiabatic case,

$B_{I}$

$\equiv$

$3 M c_{s}^{2} .$

Summary: We can combine the two cases — adiabatic and isothermal — into a single expression for $𝔊$ through a strategic use of the Kroniker delta function, $δ_{1 γ_{g}}$ , as follows:

$𝔊 = - A (\frac{R}{R_{0}})^{- 1} + (1 - δ_{1 γ_{g}}) B (\frac{R}{R_{0}})^{- 3 (γ_{g} - 1)} - δ_{1 γ_{g}} B_{I} \ln (\frac{R}{R_{0}}) + C (\frac{R}{R_{0}})^{- 2} + D (\frac{R}{R_{0}})^{3},$

Once the pressure exerted by the external medium ( $P_{e}$ ), and the configuration's mass ( $M$ ), 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 this algebraic expression for $𝔊$ describes how the free energy of the configuration will vary with the configuration's relative size ( $R / R_{0}$ ) for a given choice of $γ_{g}$ .

Whitworth (1981) and Stahler (1983)

The above formulation of a Gibbs-like free energy has been motivated by the 📚 Stahler (1983) analysis of stability of isothermal gas clouds, and it closely parallels the discussion by 📚 A. Whitworth (1981, MNRAS, Vol. 195, pp. 967 - 977) of "global gravitational stability for one-dimensional polytropes." Whitworth introduces a "global potential function," $𝔲$ , that is the sum of three "internal conserved energy modes,"

$𝔲$	$=$	$𝔤 + 𝔅_{i n} + 𝔅_{e x}$
	$=$	$- \frac{3}{5} \frac{G M_{0}^{2}}{R_{0}} (\frac{R}{R_{0}})^{- 1} + (1 - δ_{1 η}) [\frac{K M_{0}^{η}}{(η - 1)} V_{0}^{(1 - η)}] (\frac{R}{R_{0}})^{3 (1 - η)} - δ_{1 η} [3 K M_{0} \ln (\frac{R}{R_{0}})]$
		$+ P_{e x} V_{0} (\frac{R}{R_{0}})^{3}$

Clearly Whitworth's global potential function, $𝔲$ , is what we have referred to as the configuration's Gibbs-like free energy, with $η$ being used rather than $γ_{g}$ to represent the ratio of specific heats in the adiabatic case. Our expression for $𝔊$ would precisely match his expression for $𝔲$ if we chose to examine the free energy of a nonrotating configuration, that is, if we set $C = J = 0$ .

VE: Difference between revisions

Latest revision as of 13:11, 28 October 2021

Contents

Global Energy Considerations

Preface

Virial Equations (Inertial Frame)

Setting the Stage

First-Order Virial Equations

Second-Order Tensor Virial Equations

Derivation

Steady State (Virial Equilibrium)

Scalar Virial Theorem

Standard Presentation [the Virial of Clausius (1870)]

Generalization

Virial Equations (Rotating Frame)

Free Energy Expression

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Whitworth (1981) and Stahler (1983)

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@@ Line 3: / Line 3: @@
 =Global Energy Considerations=
+{| class="PGEclass" style="float:left; margin-right: 20px; border-style: solid; border-width: 3px border-color: black"
+|-
+! style="height: 125px; width: 125px; background-color:#9390DB;" |
+<font size="-1">[[H_BookTiledMenu#Context|<b>Global Energy<br />Considerations</b>]]</font>
+|}
 ==Preface==
-The astrophysics community relies heavily on the virial equations &#8212; most often in the context of the [[User:Tohline/VE#Scalar_Virial_Theorem|scalar virial theorem]] &#8212; to ascertain the basic properties of equilibrium systems.  As is described below, fundamentally the virial equations are obtained by taking moments of the Euler equation.  By examining the balance among various relevant energy reservoirs, the mathematical expression that defines virial equilibrium provides a means by which, for example, the radius of a configuration can be estimated, given a total system mass and mean system temperature.  It can also be used to estimate a system's maximum allowed rotation frequency and whether or not the properties of the equilibrium configuration will be significantly modified if the system is embedded in a hot tenuous external medium.
+The astrophysics community relies heavily on the virial equations &#8212; most often in the context of the [[#Scalar_Virial_Theorem|scalar virial theorem]] &#8212; to ascertain the basic properties of equilibrium systems.  As is described below, fundamentally the virial equations are obtained by taking moments of the Euler equation.  By examining the balance among various relevant energy reservoirs, the mathematical expression that defines virial equilibrium provides a means by which, for example, the radius of a configuration can be estimated, given a total system mass and mean system temperature.  It can also be used to estimate a system's maximum allowed rotation frequency and whether or not the properties of the equilibrium configuration will be significantly modified if the system is embedded in a hot tenuous external medium.
-As is also discussed, below, it can be even more informative to examine how a system's global, Gibbs-like free energy, <math>\mathfrak{G}</math>, varies under contraction or expansion.  Extrema in the free energy identify equilibrium configurations, for example.  For spherically symmetric systems, in particular, the [[User:Tohline/VE#Scalar_Virial_Theorem|scalar virial theorem]] is "derived" by identifying under what conditions <math>~d\mathfrak{G}/dR = 0</math>.  Furthermore, the sign of the second derivative, <math>~d^2\mathfrak{G}/dR^2</math>, tells whether or not the equilibrium state is stable or unstable.  Here we define relevant energy reservoirs that contribute to a system's global free energy.  In separate chapters we use the free energy function to help identify the properties of equilibrium systems and to examine their relative stability.
+As is also discussed, below, it can be even more informative to examine how a system's global, Gibbs-like free energy, <math>\mathfrak{G}</math>, varies under contraction or expansion.  Extrema in the free energy identify equilibrium configurations, for example.  For spherically symmetric systems, in particular, the [[#Scalar_Virial_Theorem|scalar virial theorem]] is "derived" by identifying under what conditions <math>d\mathfrak{G}/dR = 0</math>.  Furthermore, the sign of the second derivative, <math>d^2\mathfrak{G}/dR^2</math>, tells whether or not the equilibrium state is stable or unstable.  Here we define relevant energy reservoirs that contribute to a system's global free energy.  In separate chapters we use the free energy function to help identify the properties of equilibrium systems and to examine their relative stability.
 <table border="1" cellpadding="5" align="center" width="80%">
 <tr>
    <td align="center">
-<font size="+2">Why Bother?</font><br />
+'''Why Bother?'''<br />
-<font size="-1">Excerpts drawn from the introductory chapter (p. 3) of [http://ads.harvard.edu/books/1978vtsa.book/ ''The Virial Theorem in Stellar Astrophysics'' (2003)], <br />
+Excerpts drawn from the introductory chapter (p. 3) of<br />
-by George W. Collins, II</font>
+{{ Collins78figure }}
    </td>
 </tr>
 <tr><td align="left">
-<font color="#770000">'''Question'''</font>:  Why bother introducing the virial theorem and its allied free-energy expression, given that the astrophysical systems we are interested in analyzing can be fully described by solutions of the set of [[User:Tohline/PGE#Principal_Governing_Equations|Principal Governing Equations]]?
+<font color="#770000">'''Question'''</font>:  &nbsp; Why bother introducing the virial theorem and its allied free-energy expression, given that the astrophysical systems we are interested in analyzing can be fully described by solutions of the set of [[PGE#Principal_Governing_Equations|Principal Governing Equations]]?
-<font color="#770000">'''Answer'''</font>:  The [[User:Tohline/PGE#Principal_Governing_Equations|Principal Governing Equations]] are, in general, <font color="#008899">non-linear, second-order, vector differential equations which exhibit closed form solutions only in special cases.  Although additional cases may be solved numerically, insight into the behavior of systems in general is very difficult to obtain in this manner.  The virial theorem</font> and its associated free-energy expression <font color="#008899">generally deals in scalar quantities and usually is applied on a global scale.  This reduction in complexity  &#8212; from a vector description to a scalar one &#8212; frequently enables us to solve the resulting equations</font> in closed form and to ascertain more straightforwardly what physical processes are most responsible for defining properties of the solution.
+<font color="#770000">'''Answer'''</font>: &nbsp; The [[PGE#Principal_Governing_Equations|Principal Governing Equations]] are, in general, <font color="#008899">non-linear, second-order, vector differential equations which exhibit closed form solutions only in special cases.  Although additional cases may be solved numerically, insight into the behavior of systems in general is very difficult to obtain in this manner.  The virial theorem</font> and its associated free-energy expression <font color="#008899">generally deals in scalar quantities and usually is applied on a global scale.  This reduction in complexity  &#8212; from a vector description to a scalar one &#8212; frequently enables us to solve the resulting equations</font> in closed form and to ascertain more straightforwardly what physical processes are most responsible for defining properties of the solution.
-<font color="#770000">'''Caution'''</font>:  We should always keep in mind that <font color="#008899">this reduction in complexity results in a concomitant loss of information and we cannot expect to obtain as complete a description of a physical system as would be possible from a full solution of the</font> [[User:Tohline/PGE#Principal_Governing_Equations|Principal Governing Equations]].
+<font color="#770000">'''Caution'''</font>: &nbsp; We should always keep in mind that <font color="#008899">this reduction in complexity results in a concomitant loss of information and we cannot expect to obtain as complete a description of a physical system as would be possible from a full solution of the</font> [[PGE#Principal_Governing_Equations|Principal Governing Equations]].
 </td></tr>
 </table>
 ==Virial Equations (Inertial Frame)==
-Most of the material presented here has been drawn from Chandrasekhar's ''Ellipsoidal Figures of Equilibrium'' &#8212; hereafter [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] &#8212; first published in 1969.  Relying heavily on [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>'s] in-depth treatment of the topic, our aim is to highlight key aspects of the tensor-virial equations and to present them in a form that serves as a foundation for our separate discussions of the equilibrium and stability of self-gravitating fluid systems.  Strong parallels are drawn between the [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] presentation and our own so that it will be relatively straightforward for the reader to consult the [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] publication to obtain details of the various derivations. Text that appears in a green font has been drawn ''verbatim'' from this reference.
+Most of the material presented here has been drawn from Chandrasekhar's ''Ellipsoidal Figures of Equilibrium'' &#8212; hereafter [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] &#8212; first published in 1969.  Relying heavily on [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>'s] in-depth treatment of the topic, our aim is to highlight key aspects of the tensor-virial equations and to present them in a form that serves as a foundation for our separate discussions of the equilibrium and stability of self-gravitating fluid systems.  Strong parallels are drawn between the [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] presentation and our own so that it will be relatively straightforward for the reader to consult the [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] publication to obtain details of the various derivations. Text that appears in a green font has been drawn ''verbatim'' from this reference.
 ===Setting the Stage===
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>, &sect;8, p. 15] <font color="#007700">A standard technique for treating the integro-differential equations of mathematical physics is to take the moments of the equations concerned and consider suitably truncated sets of the resulting equations.  The ''virial method'' &hellip; is essentially the method of the moments applied to the solution of hydrodynamical problems in which the gravitational field of the prevailing distribution of matter is taken into account.  The ''virial equations'' of the various orders are, in fact, no more than the moments of the relevant hydrodynamical equations.</font>  In this context, Chandrasekhar's focus is on two of the four [[User:Tohline/PGE#Principal_Governing_Equations|principal governing equations]] that serve as the foundation of our entire H_Book, namely, the
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>, &sect;8, p. 15] <font color="#007700">A standard technique for treating the integro-differential equations of mathematical physics is to take the moments of the equations concerned and consider suitably truncated sets of the resulting equations.  The ''virial method'' &hellip; is essentially the method of the moments applied to the solution of hydrodynamical problems in which the gravitational field of the prevailing distribution of matter is taken into account.  The ''virial equations'' of the various orders are, in fact, no more than the moments of the relevant hydrodynamical equations.</font>  In this context, Chandrasekhar's focus is on two of the four [[PGE#Principal_Governing_Equations|principal governing equations]] that serve as the foundation of our entire H_Book, namely, the
 <div align="center">
@@ Line 38: / Line 42: @@
 ('''Momentum Conservation''')
-{{User:Tohline/Math/EQ_Euler01}}
+{{ Template:Math/EQ_Euler01 }}
 </div>
 and the
@@ Line 44: / Line 48: @@
 <span id="PGE:Poisson"><font color="#770000">'''Poisson Equation'''</font></span><br />
-{{User:Tohline/Math/EQ_Poisson01}}
+{{Template:Math/EQ_Poisson01}}
-[[Image:LSU_OriginButton.jpg|125px|link=http://www.vistrails.org/index.php/User:Tohline/SR/PoissonOrigin#Origin_of_the_Poisson_Equation]]
+[[File:OriginButton.jpg|125px|link=PGE/PoissonOrigin]]
 </div>
-In [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], the Euler equation first appears in &sect;11 (p. 20) as equation (38) and is written as,
+In [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], the Euler equation first appears in &sect;11 (p. 20) as equation (38) and is written as,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\rho \frac{du_i}{dt}</math>
+<math>\rho \frac{du_i}{dt}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- \frac{\partial p}{\partial x_i} + \rho \frac{\partial \mathfrak{B}}{\partial x_i} \, ,</math>
+<math>- \frac{\partial p}{\partial x_i} + \rho \frac{\partial \mathfrak{B}}{\partial x_i} \, ,</math>
    </td>
 </tr>
 </table>
 </div>
-and the Poisson equation appears in &sect;10 (p. 20) &#8212; specifically, the left-most component of [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>'s] equation (37) &#8212; as,
+and the Poisson equation appears in &sect;10 (p. 20) &#8212; specifically, the left-most component of [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>'s] equation (37) &#8212; as,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\nabla^2 \mathfrak{B}</math>
+<math>\nabla^2 \mathfrak{B}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- 4\pi G \rho \, .</math>
+<math>- 4\pi G \rho \, .</math>
    </td>
 </tr>
 </table>
 </div>
-It is clear, therefore, that Chandrasekhar uses the variable <math>~\vec{u}</math> instead of <math>~\vec{v}</math> to represent the inertial velocity field.  More importantly, he adopts a different variable name ''and a different sign convention'' to represent the gravitational potential, specifically,
+It is clear, therefore, that Chandrasekhar uses the variable <math>\vec{u}</math> instead of <math>\vec{v}</math> to represent the inertial velocity field.  More importantly, he adopts a different variable name ''and a different sign convention'' to represent the gravitational potential, specifically,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~ - \Phi = \mathfrak{B} </math>
+<math>- \Phi = \mathfrak{B} </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~ G \int\limits_V \frac{\rho(\vec{x}^{~'})}{|\vec{x} - \vec{x}^{~'}|} d^3x^' \, .</math>
+<math>G \int\limits_V \frac{\rho(\vec{x}^{~'})}{|\vec{x} - \vec{x}^{~'}|} d^3x^' \, .</math>
    </td>
 </tr>
 </table>
 </div>
-Hence, care must be taken to ensure that the signs on various mathematical terms are internally consistent when mapping derivations and resulting expressions from [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] into this H_Book.
+Hence, care must be taken to ensure that the signs on various mathematical terms are internally consistent when mapping derivations and resulting expressions from [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] into this H_Book.
 ===First-Order Virial Equations===
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>, &sect;11(a), p. 21] <font color="#007700">The [virial] equations of the first order are obtained by simply integrating [the Euler equation] over the instantaneous volume, <math>~V</math>, occupied by the fluid</font>.  Specifically, using our H_Book variable notation,
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>, &sect;11(a), p. 21] <font color="#007700">The [virial] equations of the first order are obtained by simply integrating [the Euler equation] over the instantaneous volume, <math>V</math>, occupied by the fluid</font>.  Specifically, using our H_Book variable notation,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\int\limits_V \rho \frac{dv_i}{dt} d^3x</math>
+<math>\int\limits_V \rho \frac{dv_i}{dt} d^3x</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- \int\limits_V \frac{\partial P}{\partial x_i} d^3x - \int\limits_V \rho \frac{\partial \Phi}{\partial x_i} d^3x \, ,</math>
+<math>- \int\limits_V \frac{\partial P}{\partial x_i} d^3x - \int\limits_V \rho \frac{\partial \Phi}{\partial x_i} d^3x \, ,</math>
    </td>
 </tr>
 </table>
 </div>
-leads to (see [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] for details),
+leads to (see [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] for details),
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\frac{d^2 I_i}{dt^2} </math>
+<math>\frac{d^2 I_i}{dt^2} </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~0 \, ,</math>
+<math>0 \, ,</math>
    </td>
 </tr>
@@ Line 136: / Line 140: @@
 <tr>
    <td align="right">
-<math>~I_i</math>
+<math>I_i</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
-<math>~\int\limits_V \rho x_i d^3x \, .</math>
+<math>\int\limits_V \rho x_i d^3x \, .</math>
    </td>
 </tr>
@@ Line 150: / Line 154: @@
 ===Second-Order Tensor Virial Equations===
-In discussing the origin of the second-order (tensor) virial equation, [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] will continue to serve as our primary reference.  However, in &sect;4.3 of their widely referenced textbook titled, "Galactic Dyamics," Binney &amp; Tremaine (1987) &#8212; hereafter [<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>] &#8212; also present a detailed derivation of the second-order virial equation, which they refer to as the ''tensor virial theorem.''  Because their presentation is set in the context of discussions of the structure of ''stellar dynamic'' systems, the [<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>] derivation fundamentally originates from the collisionless Boltzmann equation. In what follows we will identify where various key equations appear in [<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], as well as in [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], because it can sometimes be useful to compare derivations made from the stellar-dynamic versus the fluid-dynamic perspective.
+In discussing the origin of the second-order (tensor) virial equation, [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] will continue to serve as our primary reference.  However, in &sect;4.3 of their widely referenced textbook titled, "Galactic Dyamics," Binney &amp; Tremaine (1987) &#8212; hereafter [<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>] &#8212; also present a detailed derivation of the second-order virial equation, which they refer to as the ''tensor virial theorem.''  Because their presentation is set in the context of discussions of the structure of ''stellar dynamic'' systems, the [<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>] derivation fundamentally originates from the collisionless Boltzmann equation. In what follows we will identify where various key equations appear in [<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], as well as in [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], because it can sometimes be useful to compare derivations made from the stellar-dynamic versus the fluid-dynamic perspective.
 ====Derivation====
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>, &sect;11(b), p. 22] The second-order (tensor) virial equations <font color="#007700">are obtained by multiplying [the Euler equation] by <math>~x_j</math> and integrating over the volume, <math>~V</math></font>.  Specifically, again using our H_Book variable notation,
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>, &sect;11(b), p. 22] The second-order (tensor) virial equations <font color="#007700">are obtained by multiplying [the Euler equation] by <math>x_j</math> and integrating over the volume, <math>V</math></font>.  Specifically, again using our H_Book variable notation,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\int\limits_V \rho \frac{dv_i}{dt} x_j d^3x</math>
+<math>\int\limits_V \rho \frac{dv_i}{dt} x_j d^3x</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- \int\limits_V x_j \frac{\partial P}{\partial x_i} d^3x - \int\limits_V \rho x_j \frac{\partial \Phi}{\partial x_i} d^3x \, ,</math>
+<math>- \int\limits_V x_j \frac{\partial P}{\partial x_i} d^3x - \int\limits_V \rho x_j \frac{\partial \Phi}{\partial x_i} d^3x \, ,</math>
    </td>
 </tr>
 <tr>
    <td align="center" colspan="3">
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 211, Eq. (4-72)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 211, Eq. (4-72)
    </td>
 </tr>
 </table>
 </div>
-or, separating the term on the left-hand side into two physically distinguishable components &#8212; see equation 44 of [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] &#8212; this can be rewritten as,
+or, separating the term on the left-hand side into two physically distinguishable components &#8212; see equation 44 of [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] &#8212; this can be rewritten as,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\frac{d}{dt} \int\limits_V \rho v_i x_j d^3x - 2 \mathfrak{T}_{ij}</math>
+<math>\frac{d}{dt} \int\limits_V \rho v_i x_j d^3x - 2 \mathfrak{T}_{ij}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~  \delta_{ij}\Pi + \mathfrak{W}_{ij} \, ,</math>
+<math>\delta_{ij}\Pi + \mathfrak{W}_{ij} \, ,</math>
    </td>
 </tr>
 <tr>
    <td align="center" colspan="3">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 22, Eq. (47)
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 22, Eq. (47)
    </td>
 </tr>
@@ Line 209: / Line 213: @@
 <tr>
    <td align="right">
-<math>~\mathfrak{T}_{ij}</math>
+<math>\mathfrak{T}_{ij}</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
-<math>~\frac{1}{2} \int\limits_V \rho v_i v_j  d^3x </math>
+<math>\frac{1}{2} \int\limits_V \rho v_i v_j  d^3x </math>
    </td>
    <td align="center">
@@ Line 227: / Line 231: @@
    </td>
    <td align="center">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 17, Eq. (9)<br />
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 17, Eq. (9)<br />
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 212, Eq. (4-74b)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 212, Eq. (4-74b)
    </td>
 </tr>
@@ Line 234: / Line 238: @@
 <tr>
    <td align="right">
-<math>~\Pi</math>
+<math>\Pi</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
-<math>~\int\limits_V P d^3x </math>
+<math>\int\limits_V P d^3x </math>
    </td>
    <td align="center">
@@ Line 252: / Line 256: @@
    </td>
    <td align="center">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 16, Eq. (7)<br />
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 16, Eq. (7)<br />
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 212, Eq. (4-74b)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 212, Eq. (4-74b)
    </td>
 </tr>
@@ Line 259: / Line 263: @@
 <tr>
    <td align="right">
-<math>~\mathfrak{W}_{ij}</math>
+<math>\mathfrak{W}_{ij}</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
-<math>~\frac{1}{2} \int\limits_V \rho \Phi_{ij} d^3x </math>
+<math>\frac{1}{2} \int\limits_V \rho \Phi_{ij} d^3x </math>
    </td>
    <td align="center">
@@ Line 277: / Line 281: @@
    </td>
    <td align="center">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 17, Eq. (15)<br />
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 17, Eq. (15)<br />
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 68, Eq. (2-126)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 68, Eq. (2-126)
    </td>
 </tr>
@@ Line 287: / Line 291: @@
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- \int\limits_V \rho x_i \frac{\partial \Phi}{\partial x_j} d^3x </math>
+<math>- \int\limits_V \rho x_i \frac{\partial \Phi}{\partial x_j} d^3x </math>
    </td>
    <td align="center">
@@ Line 302: / Line 306: @@
    </td>
    <td align="center">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 18, Eq. (18)<br />
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 18, Eq. (18)<br />
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 67, Eq. (2-123)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 67, Eq. (2-123)
    </td>
 </tr>
@@ Line 313: / Line 317: @@
 <tr>
    <td align="right">
-<math>~ - \Phi_{ij} = \mathfrak{B}_{ij}</math>
+<math>- \Phi_{ij} = \mathfrak{B}_{ij}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~ G\int\limits_V \rho(\vec{x}^') \frac{ (x_i - x_i^')(x_j - x_j^') }{|\vec{x} - \vec{x}^{~'}|^3} d^3x^' \, ;</math>
+<math>G\int\limits_V \rho(\vec{x}^') \frac{ (x_i - x_i^')(x_j - x_j^') }{|\vec{x} - \vec{x}^{~'}|^3} d^3x^' \, ;</math>
    </td>
 </tr>
 </table>
 </div>
-this same potential energy tensor appears explicitly as part of the expression for <math>~\mathfrak{W}_{ij}</math> that is presented as Equation (2-126), on p. 67 of [<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>].
+this same potential energy tensor appears explicitly as part of the expression for <math>\mathfrak{W}_{ij}</math> that is presented as Equation (2-126), on p. 67 of [<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>].
-The antisymmetric part of this tensor expression gives (see [[User:Tohline/Appendix/References#Other_References|EFE]] for details),
+The antisymmetric part of this tensor expression gives (see [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] for details),
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\frac{d}{dt} \int\limits_V \rho (v_ix_j - v_j x_i) d^3x</math>
+<math>\frac{d}{dt} \int\limits_V \rho (v_ix_j - v_j x_i) d^3x</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~0 \, ,</math>
+<math>0 \, ,</math>
    </td>
 </tr>
 </table>
 </div>
-which <font color="#007700">expresses simply the conservation of the angular momentum of the system</font>.  The symmetric part of the tensor expression gives what is generally referred to as (see [<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>] for details) the,
+which <font color="#007700">expresses simply the conservation of the angular momentum of the system</font>.  The symmetric part of the tensor expression gives what is generally referred to as (see [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] for details) the,
 <div align="center">
 <span id="PGE:TVE"><font color="#770000">'''Tensor Virial Equation'''</font></span><br />
@@ Line 350: / Line 353: @@
 <tr>
    <td align="right">
-<math>~\frac{1}{2} \frac{d^2 I_{ij}}{dt^2}</math>
+<math>\frac{1}{2} \frac{d^2 I_{ij}}{dt^2}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~2 \mathfrak{T}_{ij} + \mathfrak{W}_{ij} + \delta_{ij}\Pi \, ,</math>
+<math>2 \mathfrak{T}_{ij} + \mathfrak{W}_{ij} + \delta_{ij}\Pi \, ,</math>
    </td>
 </tr>
 <tr>
    <td align="center" colspan="3">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 23, Eq. (51)<br />
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 23, Eq. (51)<br />
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 213, Eq. (4-78)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 213, Eq. (4-78)
    </td>
 </tr>
@@ Line 381: / Line 384: @@
 <tr>
    <td align="right">
-<math>~I_{ij}</math>
+<math>I_{ij}</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
-<math>~\int\limits_V \rho x_i  x_j d^3x </math>
+<math>\int\limits_V \rho x_i  x_j d^3x </math>
    </td>
    <td align="center">
@@ Line 399: / Line 402: @@
    </td>
    <td align="center">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 16, Eq. (4)<br />
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], p. 16, Eq. (4)<br />
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 212, Eq. (4-76)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 212, Eq. (4-76)
    </td>
 </tr>
@@ Line 407: / Line 410: @@
 ====Steady State (Virial Equilibrium)====
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b> &sect;11(b), p. 22] <font color="#007700">Under conditions of a stationary state, [the tensor virial equation] gives,</font>
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b> &sect;11(b), p. 22] <font color="#007700">Under conditions of a stationary state, [the tensor virial equation] gives,</font>
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~2 \mathfrak{T}_{ij} + \mathfrak{W}_{ij} </math>
+<math>2 \mathfrak{T}_{ij} + \mathfrak{W}_{ij} </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- \delta_{ij}\Pi \, .</math>
+<math>- \delta_{ij}\Pi \, .</math>
    </td>
 </tr>
@@ Line 425: / Line 428: @@
 <font color="#007700">[This] provides six integral relations which must obtain whenever the conditions are stationary</font>.
+{| class="PGEclass" style="float:left; margin-right: 20px; border-style: solid; border-width: 3px border-color: black"
+|-
+! style="height: 125px; width: 125px; background-color:#9390DB;" |
+<font size="-1">[[H_BookTiledMenu#Equilibrium_Structures|<b>Scalar<br />Virial<br />Theorem</b>]]</font>
+|}
 ===Scalar Virial Theorem===
 ====Standard Presentation [the Virial of Clausius (1870)]====
@@ Line 441: / Line 449: @@
    </td>
    <th align="center">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>]
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>]
 Reference
    </th>
@@ Line 448: / Line 456: @@
 <tr>
    <td align="right">
-<math>~I = \sum\limits_{i=1,3} I_{ii}</math>
+<math>I = \sum\limits_{i=1,3} I_{ii}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~\int\limits_V \rho (\vec{x}) |\vec{x}|^2 d^3x  </math>
+<math>\int\limits_V \rho (\vec{x}) |\vec{x}|^2 d^3x  </math>
    </td>
    <td align="center">
@@ Line 472: / Line 480: @@
 <tr>
    <td align="right">
-<math>~T_\mathrm{kin} = \sum\limits_{i=1,3} \mathfrak{T}_{ii}</math>
+<math>T_\mathrm{kin} = \sum\limits_{i=1,3} \mathfrak{T}_{ii}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~\frac{1}{2} \int\limits_V \rho |\vec{v}|^2  d^3x </math>
+<math>\frac{1}{2} \int\limits_V \rho |\vec{v}|^2  d^3x </math>
    </td>
    <td align="center">
@@ Line 496: / Line 504: @@
 <tr>
    <td align="right">
-<math>~W_\mathrm{grav} = \sum\limits_{i=1,3} \mathfrak{W}_{ii}</math>
+<math>W_\mathrm{grav} = \sum\limits_{i=1,3} \mathfrak{W}_{ii}</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
-<math>~- \int\limits_V \rho x_i \frac{\partial \Phi}{\partial x_i} d^3x </math>
+<math>- \int\limits_V \rho x_i \frac{\partial \Phi}{\partial x_i} d^3x </math>
    </td>
    <td align="center">
@@ Line 520: / Line 528: @@
 <tr>
    <td align="right">
-<math>~S_\mathrm{therm} = \frac{1}{2} \sum\limits_{i=1,3} \delta_{ii}\Pi</math>
+<math>S_\mathrm{therm} = \frac{1}{2} \sum\limits_{i=1,3} \delta_{ii}\Pi</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~\frac{3}{2} \int\limits_V P d^3x </math>
+<math>\frac{3}{2} \int\limits_V P d^3x </math>
    </td>
    <td align="center">
@@ Line 548: / Line 556: @@
 <tr>
    <td align="right">
-<math>~\frac{1}{2} \frac{d^2 I}{dt^2}</math>
+<math>\frac{1}{2} \frac{d^2 I}{dt^2}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~2 (T_\mathrm{kin} + S_\mathrm{therm}) +  W_\mathrm{grav} \, ;</math>
+<math>2 (T_\mathrm{kin} + S_\mathrm{therm}) +  W_\mathrm{grav} \, ;</math>
    </td>
 </tr>
@@ Line 565: / Line 573: @@
 <tr>
    <td align="right">
-<math>~2 (T_\mathrm{kin} + S_\mathrm{therm}) +  W_\mathrm{grav} </math>
+<math>2 (T_\mathrm{kin} + S_\mathrm{therm}) +  W_\mathrm{grav} </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
@@ Line 576: / Line 584: @@
 <tr>
    <td align="center" colspan="3">
-[<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 213, Eq. (4-79)
+[<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>], p. 213, Eq. (4-79)
    </td>
 </tr>
 </table>
 </div>
-(In a footnote to their Equation 4-79, [<b>[[User:Tohline/Appendix/References#BT87|<font color="red">BT87</font>]]</b>] point out that the ''scalar virial theorem'' was first proved by R. Clausius in 1870; see various links to this work under our [[User:Tohline/VE#Related_Discussions|"Related Discussions" subsection, below]].)
+(In a footnote to their Equation 4-79, [<b>[[Appendix/References#BT87|<font color="red">BT87</font>]]</b>] point out that the ''scalar virial theorem'' was first proved by R. Clausius in 1870; see various links to this work under our [[VE#Related_Discussions|"Related Discussions" subsection, below]].)
 ====Generalization====
-Chapter 24 in Volume II (''Gas Dynamics'') of [[User:Tohline/Appendix/References#Other_References|Shu's (1992) textbook]] titled, ''The Physics of Astrophysics'', presents a generalization of the scalar virial theorem that includes the effects of (a) a magnetic field that threads through a self-gravitating fluid system, and (b) an imposed surface pressure, <math>~P_e</math>, when the configuration is embedded in a hot, tenuous external medium.  Text that appears in an orange font in the following paragraph has been drawn ''verbatim'' from this reference, which we will henceforth refer to as [[User:Tohline/Appendix/References#Other_References|Shu92]].
+Chapter 24 in Volume II (''Gas Dynamics'') of [<b>[[Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>] presents a generalization of the scalar virial theorem that includes the effects of (a) a magnetic field that threads through a self-gravitating fluid system, and (b) an imposed surface pressure, <math>P_e</math>, when the configuration is embedded in a hot, tenuous external medium.  Text that appears in an orange font in the following paragraph has been drawn ''verbatim'' from this reference.
-[[User:Tohline/Appendix/References#Other_References|Shu92]] begins by adding a term to the Euler equation that accounts for <font color="orange">the Maxwell stress tensor, <math>~T_{ik}</math>, associated with the ambient magnetic field</font>, <math>~\vec{B}</math>, where,
+[<b>[[Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>] begins by adding a term to the Euler equation that accounts for <font color="orange">the Maxwell stress tensor, <math>T_{ik}</math>, associated with the ambient magnetic field</font>, <math>~\vec{B}</math>, where,
 <div align="center">
 <math>
-~T_{ik} = \frac{B_i B_k}{4\pi} - \frac{|\vec{B}|^2}{8\pi} \delta_{ik} \, .
+T_{ik} = \frac{B_i B_k}{4\pi} - \frac{|\vec{B}|^2}{8\pi} \delta_{ik} \, .
 </math>
 <br />&nbsp;<br />
-[[User:Tohline/Appendix/References#Other_References|Shu92]], p. 329, Eq. (24.3)
+[<b>[[Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>], Vol. II, p. 329, Eq. (24.3)
 </div>
-Drawing from Equation (24.1) on p. 329 of [[User:Tohline/Appendix/References#Other_References|Shu92]], the associated modified Euler equation is,
+Drawing from Equation (24.1), the associated modified Euler equation is,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\rho \frac{dv_i}{dt} </math>
+<math>\rho \frac{dv_i}{dt} </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- \frac{\partial P}{\partial x_i} - \rho \frac{\partial \Phi}{\partial x_i} + \frac{\partial T_{ik}}{\partial x_k}  \, .</math>
+<math>- \frac{\partial P}{\partial x_i} - \rho \frac{\partial \Phi}{\partial x_i} + \frac{\partial T_{ik}}{\partial x_k}  \, .</math>
    </td>
 </tr>
 </table>
 </div>
-[ [[User:Tohline/Appendix/References#Other_References|Shu92]], pp. 329-330 ] <font color="orange">If we were to multiply [this modified Euler equation] by <math>~x_m</math> and integrate over volume <math>~V</math>, we would get the [appropriately modified] ''tensor virial theorem'', the off-diagonal elements of which carry information concerning angular-momentum conservation (see Chandrasekhar's</font> EFE  <font color="orange">book for an exposition).  [Here] we shall be more interested in the trace of the tensor equation, which we may derive by simply multiplying [the modified Euler equation] by <math>~x_i</math> (with an implicit summation over repeated indices) and integrating over <math>~V</math></font>.  The resulting relation governing the equilibrium of stationary states (see [[User:Tohline/Appendix/References#Other_References|Shu92]] for derivation details), as we shall reference it, is the
+[<b>[[Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>, Vol. II, pp. 329-330] <font color="orange">If we were to multiply [this modified Euler equation] by <math>~x_m</math> and integrate over volume <math>V</math>, we would get the [appropriately modified] ''tensor virial theorem'', the off-diagonal elements of which carry information concerning angular-momentum conservation (see </font>[<b>[[Appendix/References#EFE|EFE]]</b>] <font color="orange">for an exposition).  [Here] we shall be more interested in the trace of the tensor equation, which we may derive by simply multiplying [the modified Euler equation] by <math>~x_i</math> (with an implicit summation over repeated indices) and integrating over <math>V</math></font>.  The resulting relation governing the equilibrium of stationary states (see [<b>[[Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>] for derivation details), as we shall reference it, is the
 <div align="center">
 <span id="GenTVE"><font color="#770000">'''Generalized Scalar Virial Theorem'''</font></span><br />
@@ Line 616: / Line 624: @@
 <tr>
    <td align="right">
-<math>~~2 (T_\mathrm{kin} + S_\mathrm{therm}) +  W_\mathrm{grav} + \mathcal{M}</math>
+<math>2 (T_\mathrm{kin} + S_\mathrm{therm}) +  W_\mathrm{grav} + \mathcal{M}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math> ~P_e \oint \vec{x}\cdot \hat{n} dA - \oint \vec{x}\cdot \overrightarrow{T}\hat{n} dA   \, ,</math>
+<math> P_e \oint \vec{x}\cdot \hat{n} dA - \oint \vec{x}\cdot \overrightarrow{T}\hat{n} dA   \, ,</math>
    </td>
 </tr>
 <tr>
    <td align="center" colspan="3">
-[[User:Tohline/Appendix/References#Other_References|Shu92]], p. 331, Eq. (24.12)
+[<b>[[Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>], Vol. II, p. 331, Eq. (24.12)
    </td>
 </tr>
 </table>
 </div>
-<font color="orange">where <math>~\mathcal{M}</math> equals the magnetic energy contained in volume <math>~V</math></font>,
+<font color="orange">where <math>\mathcal{M}</math> equals the magnetic energy contained in volume <math>V</math></font>,
 <div align="center">
 <math>
-~\mathcal{M} \equiv \int\limits_V \frac{|\vec{B}|^2}{8\pi} d^3x \, .
+\mathcal{M} \equiv \int\limits_V \frac{|\vec{B}|^2}{8\pi} d^3x \, .
 </math>
 <br />&nbsp;<br />
-[<b>[[User:Tohline/Appendix/References#ST83|<font color="red">ST83</font>]]</b>], p. 165, Eq. (7.1.18)<br />
+[<b>[[Appendix/References#ST83|<font color="red">ST83</font>]]</b>], p. 165, Eq. (7.1.18)<br />
-[<b>[[User:Tohline/Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>], p. 330, Eq. (24.9)
+[<b>[[Appendix/References#Shu92|<font color="red">Shu92</font>]]</b>], Vol. II, p. 330, Eq. (24.9)
 </div>
-[It should be noted that [http://adsabs.harvard.edu/abs/1953ApJ...118..116C Chandrasekhar &amp; Fermi] (1953, ApJ, 118, 116) and  [http://adsabs.harvard.edu/abs/1956MNRAS.116..503M Mestel &amp; Spitzer] (1956, MNRAS, 116, 503) provide early discussions of virial equilibrium conditions that take into account the energy associated with a magnetic field.]
+[It should be noted that {{ CF53full }} and {{ MS56full }} provide early discussions of virial equilibrium conditions that take into account the energy associated with a magnetic field.]
 ==Virial Equations (Rotating Frame)==
-As we have [[User:Tohline/PGE/RotatingFrame#Euler_Equation_.28rotating_frame.29|explained elsewhere]], when examining the equilibrium, stability, and dynamical behavior of configurations that are rotating with angular velocity, <math>~\vec\Omega_f</math>, it is useful to reference the
+As we have [[PGE/RotatingFrame#Euler_Equation_.28rotating_frame.29|explained elsewhere]], when examining the equilibrium, stability, and dynamical behavior of configurations that are rotating with angular velocity, <math>\vec\Omega_f</math>, it is useful to reference the
 <div align="center">
@@ Line 657: / Line 665: @@
-Chandrasekhar also adopts this tactic.  In his [[User:Tohline/Appendix/References#Other_References|EFE]] presentation, the equivalent expression first appears in &sect;12 as equation (62) and has the form,
+Chandrasekhar also adopts this tactic.  In [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], the equivalent expression first appears in &sect;12 as equation (62) and has the form,
 <div align="center">
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>~\rho \frac{du_i}{dt}</math>
+<math>\rho \frac{du_i}{dt}</math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~- \frac{\partial p}{\partial x_i} + \rho \frac{\partial \mathfrak{B}}{\partial x_i}
+<math>- \frac{\partial p}{\partial x_i} + \rho \frac{\partial \mathfrak{B}}{\partial x_i}
 + 2\rho \epsilon_{i \ell m}u_\ell \Omega_m + \frac{1}{2} \rho \frac{\partial}{\partial x_i}|\vec\Omega \times \vec{x}|^2 \, ,</math>
    </td>
@@ Line 674: / Line 682: @@
 </table>
 </div>
-where, as noted in [[User:Tohline/Appendix/References#Other_References|EFE]] [&sect;12, p. 25], <math>~|\vec\Omega \times \vec{x}|^2/2</math> and <math>~2\vec{u} \times \vec\Omega</math> <font color="#007700">represent the centrifugal potential and the Coriolis acceleration, respectively</font> &#8212; also see [[User:Tohline/PGE/RotatingFrame#Centrifugal_and_Coriolis_Accelerations|our related discussion of the centrifugal and Coriolis accelerations]].  As Chandrasekhar details, the Coriolis and centrifugal contributions introduce additional terms to the second-order virial, as follows:
+where, as noted in [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b> &sect;12, p. 25], the terms <math>|\vec\Omega \times \vec{x}|^2/2</math> and <math>2\vec{u} \times \vec\Omega</math> <font color="#007700">represent the centrifugal potential and the Coriolis acceleration, respectively</font> &#8212; also see [[PGE/RotatingFrame#Centrifugal_and_Coriolis_Accelerations|our related discussion of the centrifugal and Coriolis accelerations]].  As Chandrasekhar details, the Coriolis and centrifugal contributions introduce additional terms to the second-order virial, as follows:
 <div align="center">
@@ Line 681: / Line 689: @@
 <tr>
    <td align="right">
-<math>~\frac{d}{dt} \int\limits_V \rho v_i x_j d^3x </math>
+<math>\frac{d}{dt} \int\limits_V \rho v_i x_j d^3x </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~ 2 \mathfrak{T}_{ij} + \delta_{ij}\Pi + \mathfrak{W}_{ij} </math>
+<math>2 \mathfrak{T}_{ij} + \delta_{ij}\Pi + \mathfrak{W}_{ij} </math>
    </td>
 </tr>
@@ Line 699: / Line 707: @@
    </td>
    <td align="left">
-&nbsp;&nbsp;&nbsp;&nbsp;
+<math>+ 2\epsilon_{i \ell m} \Omega_m \int\limits_V \rho v_\ell x_j d^3x
-<math>~ + 2\epsilon_{i \ell m} \Omega_m \int\limits_V \rho v_\ell x_j d^3x
 + \Omega^2I_{ij} - \Omega_i \Omega_k I_{kj}\, .</math>
    </td>
@@ Line 706: / Line 713: @@
 <tr>
    <td align="center" colspan="3">
-[<b>[[User:Tohline/Appendix/References#EFE|<font color="red">EFE</font>]]</b>], &sect; 11a, p. 25, Eq. (63) and Epilogue, p. 244, Eq. (1)
+[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], &sect; 11a, p. 25, Eq. (63) and Epilogue, p. 244, Eq. (1)
    </td>
 </tr>
@@ Line 715: / Line 722: @@
 END OF DELETED COMMENT -->
-In his discussion of the ''Oscillation and Collapse of Interstellar Clouds,'' [http://adsabs.harvard.edu/abs/1976ApJ...208..113W Weber (1976)] begins with this form of the second-order virial, but adds to it a contribution due to pressure-confinement by an external medium, as [[User:Tohline/VE#Generalization|introduced above in the context of Shu's generalization]].
+In his discussion of the ''Oscillation and Collapse of Interstellar Clouds,'' {{ Weber76full }} begins with this form of the second-order virial, but adds to it a contribution due to pressure-confinement by an external medium, as [[VE#Generalization|introduced above in the context of Shu's generalization]].
 Specifically, Weber opens up his discussion with the following form of the tensor virial equations:
@@ Line 723: / Line 730: @@
 <tr>
    <td align="right">
-<math>~\frac{dL_{ij}}{dt} </math>
+<math>\frac{dL_{ij}}{dt} </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
-<math>~ 2 \mathfrak{T}_{ij} + \delta_{ij}\Pi + \mathfrak{W}_{ij} </math>
+<math>2 \mathfrak{T}_{ij} + \delta_{ij}\Pi + \mathfrak{W}_{ij} </math>
    </td>
 </tr>
@@ Line 741: / Line 748: @@
    </td>
    <td align="left">
-&nbsp;&nbsp;&nbsp;&nbsp;
+<math>+ 2\epsilon_{i \ell m} \Omega_m L_{\ell j}  + I_{jm}(|\vec\Omega|^2 \delta_{im} - \Omega_i\Omega_m)
-<math>~ + 2\epsilon_{i \ell m} \Omega_m L_{\ell j}  + I_{jm}(|\vec\Omega|^2 \delta_{im} - \Omega_i\Omega_m)
 - \oint P_e x_j n_i dS \, ,</math>
    </td>
@@ Line 748: / Line 754: @@
 <tr>
    <td align="center" colspan="3">
-[http://adsabs.harvard.edu/abs/1976ApJ...208..113W Weber (1976)], Eq. (1)
+{{ Weber76 }}, Eq. (1)
    </td>
 </tr>
@@ Line 759: / Line 765: @@
 <tr>
    <td align="right">
-<math>~L_{ij}</math>
+<math>L_{ij}</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
-<math>~\int\limits_V \rho v_i  x_j d^3x \, .</math>
+<math>\int\limits_V \rho v_i  x_j d^3x \, .</math>
    </td>
 </tr>
@@ Line 778: / Line 784: @@
 </math>
 </div>
-Here, we have explicitly included the gravitational potential energy, <math>~W_\mathrm{grav}</math>, the ordered kinetic energy, <math>~T_\mathrm{kin}</math>, a term that accounts for surface effects if the configuration of volume <math>~V</math> is embedded in an external medium of pressure <math>~P_e</math>, and <math>~\mathfrak{S}_\mathrm{therm}</math>, the reservoir of thermodynamic energy that is available to perform work as the system expands or contracts.  Our above discussion of the [[User:Tohline/VE#Scalar_Virial_Theorem|scalar virial theorem]] provides mathematical definitions of each of these energy terms, except for <math>~\mathfrak{S}_\mathrm{therm},</math>, which we discuss now.
+Here, we have explicitly included the gravitational potential energy, <math>W_\mathrm{grav}</math>, the ordered kinetic energy, <math>T_\mathrm{kin}</math>, a term that accounts for surface effects if the configuration of volume <math>V</math> is embedded in an external medium of pressure <math>P_e</math>, and <math>\mathfrak{S}_\mathrm{therm}</math>, the reservoir of thermodynamic energy that is available to perform work as the system expands or contracts.  Our above discussion of the [[#Scalar_Virial_Theorem|scalar virial theorem]] provides mathematical definitions of each of these energy terms, except for <math>\mathfrak{S}_\mathrm{therm}</math>, which we discuss now.
 ===Reservoir of Thermodynamic Energy===
-<math>~\mathfrak{S}_\mathrm{therm}</math> derives from the differential, "PdV" work that is often discussed in the context of thermodynamic systems.  It should be made clear that, here, "dV" refers to the differential volume ''per unit mass,''  so it should be written as "<math>~d(\rho^{-1})</math>", to be consistent with the notation used throughout this H_Book.  Therefore, the differential thermodynamic work is,
+<math>\mathfrak{S}_\mathrm{therm}</math> derives from the differential, "PdV" work that is often discussed in the context of thermodynamic systems.  It should be made clear that, here, "dV" refers to the differential volume ''per unit mass,''  so it should be written as "<math>~d(\rho^{-1})</math>", to be consistent with the notation used throughout this H_Book.  Therefore, the differential thermodynamic work is,
 <div align="center">
 <math>d\mathfrak{w} = Pd(1/\rho) = -  \biggl( \frac{P}{\rho^2} \biggr) d\rho \, .</math>
 </div>
-After an ''evolutionary'' equation of state has been adopted, this differential relationship can be integrated to give an expression for the energy per unit mass, <math>~\mathfrak{w}</math>, that is potentially available for work.  Then we define the thermodynamic energy reservoir as,
+After an ''evolutionary'' equation of state has been adopted, this differential relationship can be integrated to give an expression for the energy per unit mass, <math>\mathfrak{w}</math>, that is potentially available for work.  Then we define the thermodynamic energy reservoir as,
 <div align="center">
 <math>\mathfrak{S}_\mathrm{therm} \equiv - \int \mathfrak{w} ~dm \, .</math>
@@ Line 793: / Line 799: @@
 If each element of gas maintains its temperature when the system undergoes compression or expansion &#8212; that is, if the compression/expansion is isothermal &#8212; then, the relevant evolutionary equation of state is,
 <div align="center">
-<math>~P = c_s^2 \rho \, ,</math>
+<math>P = c_s^2 \rho \, ,</math>
 </div>
-where the constant, <math>~c_s</math>, is the isothermal sound speed.  In this case, the expression for the differential thermodynamic work becomes,
+where the constant, <math>c_s</math>, is the isothermal sound speed.  In this case, the expression for the differential thermodynamic work becomes,
 <div align="center">
 <math>d\mathfrak{w} =  -  \biggl( \frac{c_s^2}{\rho} \biggr) d\rho =  -  c_s^2 d\ln\rho \, .</math>
@@ Line 803: / Line 809: @@
 <math>\mathfrak{w} = -  c_s^2 \ln \biggl(\frac{\rho}{\rho_0}\biggr) \, ,</math>
 </div>
-where, <math>~\rho_0</math> is a (as yet unspecified) reference density, and integration throughout the configuration gives (for the isothermal case),
+where, <math>\rho_0</math> is a (as yet unspecified) reference density, and integration throughout the configuration gives (for the isothermal case),
 <div align="center">
 <math>\mathfrak{S}_\mathrm{therm} = +  \int c_s^2 \ln \biggl(\frac{\rho}{\rho_0}\biggr) dm \, .</math>
@@ Line 813: / Line 819: @@
 <math>P = K \rho^{\gamma_g} \, ,</math>
 </div>
-where, <math>~K</math> specifies the specific entropy of the gas and {{User:Tohline/Math/MP_AdiabaticIndex}} is the ratio of specific heats that is relevant to the phase of compression/expansion.  In this case, the expression for the differential thermodynamic work becomes,
+where, <math>K</math> specifies the specific entropy of the gas and {{ Template:Math/MP_AdiabaticIndex }} is the ratio of specific heats that is relevant to the phase of compression/expansion.  In this case, the expression for the differential thermodynamic work becomes,
 <div align="center">
 <math>d\mathfrak{w} =  -  K \rho^{{\gamma_g}-2} d\rho =  -  \frac{K}{({\gamma_g}-1)} d\rho^{{\gamma_g}-1} \, .</math>
@@ Line 827: / Line 833: @@
 = \frac{2}{3({\gamma_g}-1)} S_\mathrm{therm} \, ,</math>
 </div>
-where, as introduced in our above discussion of the [[User:Tohline/VE#Scalar_Virial_Theorem|scalar virial theorem]], <math>~S_\mathrm{therm}</math> is the system's total thermal (''i.e.,'' random kinetic) energy.
+where, as introduced in our above discussion of the [[#Scalar_Virial_Theorem|scalar virial theorem]], <math>S_\mathrm{therm}</math> is the system's total thermal (''i.e.,'' random kinetic) energy.
 ====Relationship to the System's Internal Energy====
-It is instructive to tie this introductory material to the classic discussion of thermodynamic systems, which relates a change in the system's internal energy per unit mass, <math>~\Delta u_\mathrm{int}</math>, to the differential work, <math>~\Delta \mathfrak{w}</math>, via the expression,
+It is instructive to tie this introductory material to the classic discussion of thermodynamic systems, which relates a change in the system's internal energy per unit mass, <math>\Delta u_\mathrm{int}</math>, to the differential work, <math>\Delta \mathfrak{w}</math>, via the expression,
 <div align="center">
-<math>~\Delta u_\mathrm{int} = \Delta Q - \Delta \mathfrak{w} \, ,</math>
+<math>\Delta u_\mathrm{int} = \Delta Q - \Delta \mathfrak{w} \, ,</math>
 </div>
-where, <math>~\Delta Q</math> is the change in heat content of the system.
+where, <math>\Delta Q</math> is the change in heat content of the system.
-'''Isothermal Evolutions''':  Because the internal energy is only a function of the temperature, we can set <math>~\Delta u_\mathrm{int} = 0</math> for expansions or contractions that occur isothermally.  Hence, for isothermal evolutions the change in heat content can immediately be deduced from the expression derived for the differential work; specifically, <math>~\Delta Q = \Delta \mathfrak{w}</math>.
+'''Isothermal Evolutions''':  Because the internal energy is only a function of the temperature, we can set <math>\Delta u_\mathrm{int} = 0</math> for expansions or contractions that occur isothermally.  Hence, for isothermal evolutions the change in heat content can immediately be deduced from the expression derived for the differential work; specifically, <math>\Delta Q = \Delta \mathfrak{w}</math>.
-'''Adiabatic Evolutions''':  By definition, <math>~\Delta Q = 0</math> for adiabatic evolutions, in which case we find <math>~\Delta u_\mathrm{int} = - \Delta \mathfrak{w}</math>.  The definition of the thermodynamic energy reservoir can therefore be rewritten as,
+'''Adiabatic Evolutions''':  By definition, <math>\Delta Q = 0</math> for adiabatic evolutions, in which case we find <math>\Delta u_\mathrm{int} = - \Delta \mathfrak{w}</math>.  The definition of the thermodynamic energy reservoir can therefore be rewritten as,
 <div align="center">
 <math>\mathfrak{S}_\mathrm{therm} = - \int \mathfrak{w} ~dm = + \int u_\mathrm{int} ~dm = U_\mathrm{int} \, .</math>
 </div>
-Quite generally, then &#8212; in sync with the above derivation &#8212; we can replace <math>~\mathfrak{S}_\mathrm{therm}</math> by,
+Quite generally, then &#8212; in sync with the above derivation &#8212; we can replace <math>\mathfrak{S}_\mathrm{therm}</math> by,
 <div align="center">
 <math>~U_\mathrm{int} = \frac{2}{3(\gamma_g-1)} S_\mathrm{therm} \, ,</math>
@@ Line 849: / Line 855: @@
 ===Illustration===
-As is derived in [[User:Tohline/SphericallySymmetricConfigurations/Virial#Virial_Equilibrium|an accompanying discussion]], for a uniform-density, uniformly rotating, spherically symmetric configuration of mass <math>~M</math> and radius <math>~R</math>,
+As is derived in [[SSCpt1/Virial#Virial_Equilibrium|an accompanying discussion]], for a uniform-density, uniformly rotating, spherically symmetric configuration of mass <math>M</math> and radius <math>R</math>,
 <div align="center">
 <table border="0" cellpadding="5">
@@ Line 855: / Line 861: @@
    <td align="right">
 <math>
-~W_\mathrm{grav}
+W_\mathrm{grav}
 </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
 <math>
-~ - \frac{3}{5} \frac{GM^2}{R_0} \biggl( \frac{R}{R_0} \biggr)^{-1} \, ,
+- \frac{3}{5} \frac{GM^2}{R_0} \biggl( \frac{R}{R_0} \biggr)^{-1} \, ,
 </math>
    </td>
 </tr>
 <tr>
    <td align="right">
 <math>
-~ T_\mathrm{kin}
+T_\mathrm{kin}
 </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
 <math>
-~\frac{5}{4} \frac{J^2}{MR_0^2} \biggl( \frac{R}{R_0} \biggr)^{-2} \, ,
+\frac{5}{4} \frac{J^2}{MR_0^2} \biggl( \frac{R}{R_0} \biggr)^{-2} \, ,
 </math>
    </td>
@@ Line 887: / Line 892: @@
    <td align="right">
 <math>
-~V
+V
 </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
 <math>
-~\frac{4}{3} \pi R_0^3 \biggl( \frac{R}{R_0} \biggr)^{3} \, ,
+\frac{4}{3} \pi R_0^3 \biggl( \frac{R}{R_0} \biggr)^{3} \, ,
 </math>
    </td>
@@ Line 902: / Line 907: @@
 </table>
 </div>
-where, <math>~J</math> is the system's total angular momentum and <math>~R_0</math> is a reference length scale.
+where, <math>J</math> is the system's total angular momentum and <math>R_0</math> is a reference length scale.
 '''Adiabatic Systems''':  If, upon compression or expansion, the gaseous configuration behaves adiabatically, the reservoir of thermodynamic energy is,
@@ Line 910: / Line 915: @@
    <td align="right">
 <math>
-~\mathfrak{S}_\mathrm{therm} = U_\mathrm{int} = \frac{M K \rho^{\gamma_g-1}}{(\gamma_g - 1)}
+\mathfrak{S}_\mathrm{therm} = U_\mathrm{int} = \frac{M K \rho^{\gamma_g-1}}{(\gamma_g - 1)}
 = \frac{M K }{(\gamma_g - 1)} \biggl( \frac{3M}{4\pi R_0^3} \biggr)^{\gamma_g-1} \biggl( \frac{R}{R_0} \biggr)^{-3(\gamma_g-1)} \, .
 </math>
@@ Line 929: / Line 934: @@
 <tr>
    <td align="right">
-<math>~A</math>
+<math>A</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
@@ Line 941: / Line 946: @@
 <tr>
    <td align="right">
-<math>~B</math>
+<math>B</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
@@ Line 955: / Line 960: @@
 <tr>
    <td align="right">
-<math>~C</math>
+<math>C</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
@@ Line 969: / Line 974: @@
 <tr>
    <td align="right">
-<math>~D</math>
+<math>D</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
@@ Line 983: / Line 988: @@
 </div>
-'''Isothermal Systems''':  If, upon compression or expansion, the configuration remains isothermal, [see, also, Appendix A of [http://adsabs.harvard.edu/abs/1983ApJ...268..165S Stahler] (1983, ApJ, 268, 16)], the reservoir of thermal energy is,
+'''Isothermal Systems''':  If, upon compression or expansion, the configuration remains isothermal &#8212; also see Appendix A of {{ Stahler83full }} &#8212; the reservoir of thermal energy is,
 <div align="center">
@@ Line 990: / Line 995: @@
    <td align="right">
 <math>
-~\mathfrak{S}_\mathrm{therm}
+\mathfrak{S}_\mathrm{therm}
 </math>
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
@@ Line 1,016: / Line 1,021: @@
 <tr>
    <td align="right">
-<math>~B_I</math>
+<math>B_I</math>
    </td>
    <td align="center">
-<math>~\equiv</math>
+<math>\equiv</math>
    </td>
    <td align="left">
 <math>
-~3Mc_s^2 \, .
+Mc_s^2 \, .
 </math>
    </td>
@@ Line 1,037: / Line 1,042: @@
 </math>
 </div>
-Once the pressure exerted by the external medium (<math>~P_e</math>), and the configuration's mass (<math>~M</math>), angular momentum (<math>~J</math>), and specific entropy (via <math>~K</math>) &#8212; or, in the isothermal case, sound speed (<math>~c_s</math>) &#8212;  have been specified, the values of all of the coefficients are known and this algebraic expression for <math>~\mathfrak{G}</math> describes how the free energy of the configuration will vary with the configuration's relative size (<math>~R/R_0</math>) for a given choice of <math>~\gamma_g</math>.
+Once the pressure exerted by the external medium (<math>P_e</math>), and the configuration's mass (<math>M</math>), angular momentum (<math>J</math>), and specific entropy (via <math>K</math>) &#8212; or, in the isothermal case, sound speed (<math>c_s</math>) &#8212;  have been specified, the values of all of the coefficients are known and this algebraic expression for <math>\mathfrak{G}</math> describes how the free energy of the configuration will vary with the configuration's relative size (<math>R/R_0</math>) for a given choice of <math>\gamma_g</math>.
 ==Whitworth (1981) and Stahler (1983)==
-The above formulation of a [[User:Tohline/VE#Free_Energy_Expression|Gibbs-like free energy]] has been motivated by [http://adsabs.harvard.edu/abs/1983ApJ...268..165S Stahler's] (1983, ApJ, 268, 16) analysis of the stability of isothermal gas clouds, and it closely parallels [http://adsabs.harvard.edu/abs/1981MNRAS.195..967W Whitworth's] (1981, MNRAS, 195, 967) discussion of the "global gravitational stability for one-dimensional polytropes."  Whitworth introduces a "global potential function," <math>\mathfrak{u}</math>, that is the sum of three "internal conserved energy modes,"
+The above formulation of a [[#Free_Energy_Expression|Gibbs-like free energy]] has been motivated by the {{ Stahler83 }} analysis of stability of isothermal gas clouds, and it closely parallels the discussion by {{ Whitworth81full }} of "global gravitational stability for one-dimensional polytropes."  Whitworth introduces a "global potential function," <math>\mathfrak{u}</math>, that is the sum of three "internal conserved energy modes,"
 <div align="center">
 <table border="0">
@@ Line 1,046: / Line 1,051: @@
    <td align="right">
 <math>
-~\mathfrak{u}
+\mathfrak{u}
 </math>
    </td>
    <td align="center">
 <math>
-~=
+=
 </math>
    </td>
    <td align="left">
 <math>
-~\mathfrak{g} + \mathfrak{B}_\mathrm{in} + \mathfrak{B}_\mathrm{ex}
+\mathfrak{g} + \mathfrak{B}_\mathrm{in} + \mathfrak{B}_\mathrm{ex}
 </math>
    </td>
@@ Line 1,066: / Line 1,071: @@
    </td>
    <td align="center">
-<math>~=</math>
+<math>=</math>
    </td>
    <td align="left">
 &nbsp;
 <math>
-~~~ - \frac{3}{5} \frac{GM_0^2}{R_0} \biggl(\frac{R}{R_0} \biggr)^{-1}
+- \frac{3}{5} \frac{GM_0^2}{R_0} \biggl(\frac{R}{R_0} \biggr)^{-1}
 + (1-\delta_{1\eta})\biggl[ \frac{KM_0^\eta}{(\eta - 1)} V_0^{(1-\eta)} \biggr] \biggl(\frac{R}{R_0}\biggr)^{3(1-\eta)}
 - \delta_{1\eta} \biggl[ 3KM_0 \ln\biggl(\frac{R}{R_0} \biggr) \biggr]
@@ Line 1,088: / Line 1,093: @@
 &nbsp;
 <math>
-~+ P_\mathrm{ex} V_0 \biggl( \frac{R}{R_0} \biggr)^{3}
++ P_\mathrm{ex} V_0 \biggl( \frac{R}{R_0} \biggr)^{3}
 </math>
    </td>
@@ Line 1,095: / Line 1,100: @@
 </table>
 </div>
-Clearly Whitworth's global potential function, <math>~\mathfrak{u}</math>, is what we have referred to as the configuration's Gibbs-like free energy, with <math>~\eta</math> being used rather than <math>~\gamma_g</math> to represent the ratio of specific heats in the adiabatic case.  Our expression for <math>~\mathfrak{G}</math> would precisely match his expression for <math>~\mathfrak{u}</math> if we chose to examine the free energy of a nonrotating configuration, that is, if we set <math>~C=J=0</math>.
+Clearly Whitworth's global potential function, <math>\mathfrak{u}</math>, is what we have referred to as the configuration's Gibbs-like free energy, with <math>\eta</math> being used rather than <math>\gamma_g</math> to represent the ratio of specific heats in the adiabatic case.  Our expression for <math>\mathfrak{G}</math> would precisely match his expression for <math>\mathfrak{u}</math> if we chose to examine the free energy of a nonrotating configuration, that is, if we set <math>C=J=0</math>.
-=Related Discussions=
-* Clausius, R. J. E. (1870). "On a Mechanical Theorem Applicable to Heat," [http://www.tandfonline.com/doi/abs/10.1080/.U35XrK1dUys ''Philosophical Magazine, Ser. 4, vol. 40, issue 265], pp. 122-127.
-** [http://books.google.com/books?id=Zk0wAAAAIAAJ&pg=PA122&lpg=PA122&dq=Mechanical+Theorem+Applicable+to+Heat&source=bl&ots=dhToAIe8k9&sig=0TaKVTmMnZ5qWvxLkdzuExMoU-U&hl=en&sa=X&ei=YFd-U5qiGdizyASS74CIAw&ved=0CDYQ6AEwAQ#v=onepage&q=Mechanical%20Theorem%20Applicable%20to%20Heat&f=false Google Book Reference]
-** [http://www.elastic-plastic.de/Clausius1870.pdf Alternative, stand-alone document]
-* [http://en.wikipedia.org/wiki/Virial_theorem Wikipedia discussion of the virial theorem]
-* [http://ads.harvard.edu/books/1978vtsa.book/ The Virial Theorem in Stellar Astrophysics (1978)] by George W. Collins, II
 =See Also=
 <ul>
-<li>[[User:Tohline/SphericallySymmetricConfigurations/IndexFreeEnergy#Index_to_Free-Energy_Analyses|Index to a Variety of Free-Energy and/or Virial Analyses]]</li>
+  <li>{{ Clausius1870full }},  ''On a Mechanical Theorem Applicable to Heat''</li>
+  <ul>
+    <li>[http://books.google.com/books?id=Zk0wAAAAIAAJ&pg=PA122&lpg=PA122&dq=Mechanical+Theorem+Applicable+to+Heat&source=bl&ots=dhToAIe8k9&sig=0TaKVTmMnZ5qWvxLkdzuExMoU-U&hl=en&sa=X&ei=YFd-U5qiGdizyASS74CIAw&ved=0CDYQ6AEwAQ#v=onepage&q=Mechanical%20Theorem%20Applicable%20to%20Heat&f=false Google Book Reference]
+    </li>
+    <li>
+[http://www.elastic-plastic.de/Clausius1870.pdf Alternative, stand-alone document]
+    </li>
+  </ul>
+  <li>[http://en.wikipedia.org/wiki/Virial_theorem Wikipedia discussion of the virial theorem]</li>
+  <li>{{ Collins78full }}</li>
+<li>[[SphericallySymmetricConfigurations/IndexFreeEnergy#Index_to_Free-Energy_Analyses|Index to a Variety of Free-Energy and/or Virial Analyses]]</li>
 </ul>
 {{ SGFfooter }}

VE: Difference between revisions

Latest revision as of 13:11, 28 October 2021

Global Energy Considerations

Preface

Virial Equations (Inertial Frame)

Setting the Stage

First-Order Virial Equations

Second-Order Tensor Virial Equations

Derivation

Steady State (Virial Equilibrium)

Scalar Virial Theorem

Standard Presentation [the Virial of Clausius (1870)]

Generalization

Virial Equations (Rotating Frame)

Free Energy Expression

Reservoir of Thermodynamic Energy

Isothermal Systems

Adiabatic Systems

Relationship to the System's Internal Energy

Illustration

Whitworth (1981) and Stahler (1983)

See Also

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