Latest revision as of 15:36, 16 November 2024

Parabolic Density Distribution[edit]

Part I: Gravitational Potential

Part II: Spherical Structures

Part III: Axisymmetric Equilibrium Structures

Old: 1^st thru 7^th tries
Old: 8^th thru 10^th tries

Part IV: Triaxial Equilibrium Structures (Exploration)

Axisymmetric (Oblate) Equilibrium Structures[edit]

Tentative Summary[edit]

Known Relations[edit]

Density:	$\frac{ρ (ϖ, z)}{ρ_{c}}$	$=$	$[1 - χ^{2} - ζ^{2} (1 - e^{2})^{- 1}],$
Gravitational Potential:	$\frac{Φ_{g r a v} (ϖ, z)}{(- π G ρ_{c} a_{ℓ}^{2})}$	$=$	$\frac{1}{2} I_{B T} - A_{ℓ} χ^{2} - A_{s} ζ^{2} + \frac{1}{2} [(A_{s s} a_{ℓ}^{2}) ζ^{4} + 2 (A_{ℓ s} a_{ℓ}^{2}) χ^{2} ζ^{2} + (A_{ℓ ℓ} a_{ℓ}^{2}) χ^{4}] .$
	$\Rightarrow \frac{\partial}{\partial ζ} [\frac{Φ_{g r a v}}{(- π G ρ_{c} a_{ℓ}^{2})}]$	$=$	$2 (A_{ℓ s} a_{ℓ}^{2}) χ^{2} ζ - 2 A_{s} ζ + 2 (A_{s s} a_{ℓ}^{2}) ζ^{3} .$
	and, $\frac{\partial}{\partial χ} [\frac{Φ_{g r a v}}{(- π G ρ_{c} a_{ℓ}^{2})}]$	$=$	$2 (A_{ℓ s} a_{ℓ}^{2}) χ ζ^{2} - 2 A_{ℓ} χ + 2 (A_{ℓ ℓ} a_{ℓ}^{2}) χ^{3} .$

where, $χ \equiv ϖ / a_{ℓ}$ and $ζ \equiv z / a_{ℓ}$ , and the relevant index symbol expressions are:

$I_{B T}$	$=$	$2 A_{ℓ} + A_{s} (1 - e^{2}) = 2 (1 - e^{2})^{1 / 2} [\frac{\sin^{- 1} e}{e}];$	[1.7160030]
$A_{ℓ}$	$=$	$\frac{1}{e^{2}} [\frac{\sin^{- 1} e}{e} - (1 - e^{2})^{1 / 2}] (1 - e^{2})^{1 / 2};$	[0.6055597]
$A_{s}$	$=$	$\frac{2}{e^{2}} [(1 - e^{2})^{- 1 / 2} - \frac{\sin^{- 1} e}{e}] (1 - e^{2})^{1 / 2};$	[0.7888807]
$a_{ℓ}^{2} A_{ℓ ℓ}$	$=$	$\frac{1}{4 e^{4}} {- (3 + 2 e^{2}) (1 - e^{2}) + 3 (1 - e^{2})^{1 / 2} [\frac{\sin^{- 1} e}{e}]} = [\frac{1}{2} - \frac{(A_{s} - A_{ℓ})}{4 e^{2}}];$	[0.3726937]
$a_{ℓ}^{2} A_{s s}$	$=$	$\frac{2}{3} {\frac{(4 e^{2} - 3)}{e^{4} (1 - e^{2})} + \frac{3 (1 - e^{2})^{1 / 2}}{e^{4}} [\frac{\sin^{- 1} e}{e}]} = \frac{2}{3} [(1 - e^{2})^{- 1} - \frac{(A_{s} - A_{ℓ})}{e^{2}}];$	[0.7021833]
$a_{ℓ}^{2} A_{ℓ s}$	$=$	$\frac{1}{e^{4}} {(3 - e^{2}) - 3 (1 - e^{2})^{1 / 2} [\frac{\sin^{- 1} e}{e}]} = \frac{(A_{s} - A_{ℓ})}{e^{2}},$	[0.5092250]

where the eccentricity,

$e \equiv [1 - (\frac{a_{s}}{a_{ℓ}})^{2}]^{1 / 2} .$

NOTE: The posted numerical evaluations (inside square brackets) assume that the configuration's eccentricity is $e = 0.6 \Rightarrow a_{s} / a_{ℓ} = 0.8$ .

Drawing from our separate "6^th Try" discussion — and as has been highlighted here for example — for the axisymmetric configurations under consideration, the ${\hat{e}}_{z}$ and ${\hat{e}}_{ϖ}$ components of the Euler equation become, respectively,

${\hat{e}}_{z}$ :	$0$	=	$[\frac{1}{ρ} \frac{\partial P}{\partial z} + \frac{\partial Φ}{\partial z}]$
${\hat{e}}_{ϖ}$ :	$\frac{j^{2}}{ϖ^{3}}$	=	$[\frac{1}{ρ} \frac{\partial P}{\partial ϖ} + \frac{\partial Φ}{\partial ϖ}]$

Multiplying the ${\hat{e}}_{z}$ component through by length $(a_{ℓ})$ and dividing through by the square of the velocity $(π G ρ_{c} a_{ℓ}^{2})$ , we have,

$0$	=	$[\frac{1}{ρ} \frac{\partial P}{\partial z} + \frac{\partial Φ}{\partial z}] \frac{a_{ℓ}}{(π G ρ_{c} a_{ℓ}^{2})}$
	=	$\frac{ρ_{c}}{ρ} \cdot \frac{\partial}{\partial ζ} [\frac{P}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] - \frac{\partial}{\partial ζ} [\frac{Φ}{(- π G ρ_{c} a_{ℓ}^{2})}]$
$\Rightarrow \frac{\partial}{\partial ζ} [\frac{P}{(π G ρ_{c}^{2} a_{ℓ}^{2})}]$	=	$\frac{ρ}{ρ_{c}} \cdot \frac{\partial}{\partial ζ} [\frac{Φ}{(- π G ρ_{c} a_{ℓ}^{2})}]$
	=	$\frac{ρ}{ρ_{c}} \cdot [2 (A_{ℓ s} a_{ℓ}^{2}) χ^{2} ζ - 2 A_{s} ζ + 2 (A_{s s} a_{ℓ}^{2}) ζ^{3}]$

Multiplying the ${\hat{e}}_{ϖ}$ component through by length $(a_{ℓ})$ and dividing through by the square of the velocity $(π G ρ_{c} a_{ℓ}^{2})$ , we have,

${\hat{e}}_{ϖ}$ :	$\frac{j^{2}}{ϖ^{3}} \cdot \frac{a_{ℓ}}{(π G ρ_{c} a_{ℓ}^{2})}$	=	$[\frac{1}{ρ} \frac{\partial P}{\partial ϖ} + \frac{\partial Φ_{g r a v}}{\partial ϖ}] \frac{a_{ℓ}}{(π G ρ_{c} a_{ℓ}^{2})}$
	$\Rightarrow \frac{1}{χ^{3}} \cdot \frac{j^{2}}{(π G ρ_{c} a_{ℓ}^{4})}$	=	$\frac{ρ_{c}}{ρ} \cdot \frac{\partial}{\partial χ} [\frac{P}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] - \frac{\partial}{\partial χ} [\frac{Φ_{g r a v}}{(- π G ρ_{c} a_{ℓ}^{2})}]$

Play With Vertical Pressure Gradient[edit]

$[\frac{1}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] \frac{\partial P}{\partial ζ}$	$=$	$[1 - χ^{2} - ζ^{2} (1 - e^{2})^{- 1}] [2 A_{ℓ s} a_{ℓ}^{2} χ^{2} ζ - 2 A_{s} ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3}]$
	$=$	$[(2 A_{ℓ s} a_{ℓ}^{2} χ^{2} - 2 A_{s}) ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3}] - χ^{2} [(2 A_{ℓ s} a_{ℓ}^{2} χ^{2} - 2 A_{s}) ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3}] - ζ^{2} (1 - e^{2})^{- 1} [(2 A_{ℓ s} a_{ℓ}^{2} χ^{2} - 2 A_{s}) ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3}]$
	$=$	$(2 A_{ℓ s} a_{ℓ}^{2} χ^{2} - 2 A_{s}) ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3} - (2 A_{ℓ s} a_{ℓ}^{2} χ^{4} - 2 A_{s} χ^{2}) ζ - 2 A_{s s} a_{ℓ}^{2} χ^{2} ζ^{3} - (1 - e^{2})^{- 1} [(2 A_{ℓ s} a_{ℓ}^{2} χ^{2} - 2 A_{s}) ζ^{3} + 2 A_{s s} a_{ℓ}^{2} ζ^{5}]$
	$=$	$[(2 A_{ℓ s} a_{ℓ}^{2} χ^{2} - 2 A_{s}) - (2 A_{ℓ s} a_{ℓ}^{2} χ^{4} - 2 A_{s} χ^{2})] ζ + [2 A_{s s} a_{ℓ}^{2} - 2 A_{s s} a_{ℓ}^{2} χ^{2} - (1 - e^{2})^{- 1} (2 A_{ℓ s} a_{ℓ}^{2} χ^{2} - 2 A_{s})] ζ^{3} + [- (1 - e^{2})^{- 1} 2 A_{s s} a_{ℓ}^{2}] ζ^{5} .$

Integrate over $ζ$ gives …

$P_{d e d u c e d}^{*} \equiv [\frac{1}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] \int [\frac{\partial P}{\partial ζ}] d ζ$	$=$	$\overset{c o e f 1}{\overset{⏞}{[(A_{ℓ s} a_{ℓ}^{2} χ^{2} - A_{s}) - (A_{ℓ s} a_{ℓ}^{2} χ^{4} - A_{s} χ^{2})]}} ζ^{2} + \underset{c o e f 2}{\underset{⏟}{\frac{1}{2} [A_{s s} a_{ℓ}^{2} - A_{s s} a_{ℓ}^{2} χ^{2} - (1 - e^{2})^{- 1} (A_{ℓ s} a_{ℓ}^{2} χ^{2} - A_{s})]}} ζ^{4} + \overset{c o e f 3}{\overset{⏞}{\frac{1}{3} [- (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2}]}} ζ^{6} + c o n s t$
	$=$	$[- A_{s} ζ^{2} + \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} + \frac{1}{2} (1 - e^{2})^{- 1} A_{s} ζ^{4} - \frac{1}{3} (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2} ζ^{6}] χ^{0} + [A_{ℓ s} a_{ℓ}^{2} ζ^{2} + A_{s} ζ^{2} - \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} - \frac{1}{2} (1 - e^{2})^{- 1} (A_{ℓ s} a_{ℓ}^{2} ζ^{4})] χ^{2} + [- A_{ℓ s} a_{ℓ}^{2} ζ^{2}] χ^{4} + c o n s t .$

If I am interpreting this correctly, $P_{d e d u c e d}^{*}$ should tell how the normalized pressure varies with $ζ$ , for a fixed choice of $0 \leq χ \leq 1$ . Again, for a fixed choice of $χ$ , we want to specify the value of the "const." — hereafter, $C_{χ}$ — such that $P_{d e d u c e d}^{*} = 0$ at the surface of the configuration; but at the surface where $ρ / ρ_{c} = 0$ , it must also be true that,

at the surface …

ζ^{2}

=

$(1 - e^{2}) [1 - χ^{2} - {\frac{ρ}{ρ_{c}}}^{0}] = (1 - e^{2}) (1 - χ^{2}) .$

Hence (numerical evaluations assume χ = 0.6 as well as e = 0.6),

- C_{χ}

=

$\overset{c o e f 1 = - 0.38756}{\overset{⏞}{[(A_{ℓ s} a_{ℓ}^{2} χ^{2} - A_{s}) - (A_{ℓ s} a_{ℓ}^{2} χ^{4} - A_{s} χ^{2})]}} [(1 - e^{2}) (1 - χ^{2})] + \underset{c o e f 2 = 0.69779}{\underset{⏟}{\frac{1}{2} [A_{s s} a_{ℓ}^{2} - A_{s s} a_{ℓ}^{2} χ^{2} - (1 - e^{2})^{- 1} (A_{ℓ s} a_{ℓ}^{2} χ^{2} - A_{s})]}} [(1 - e^{2}) (1 - χ^{2})]^{2} + \overset{c o e f 3 = - 0.36572}{\overset{⏞}{\frac{1}{3} [- (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2}]}} [(1 - e^{2}) (1 - χ^{2})]^{3} = - 0.66807 .$

Central Pressure

At the center of the configuration — where $ζ = χ = 0$ — we see that,

$- C_{χ} \|_{χ = 0}$	$=$	$[(- A_{s})] (1 - e^{2}) + \frac{1}{2} [A_{s s} a_{ℓ}^{2} + (1 - e^{2})^{- 1} A_{s}] (1 - e^{2})^{2} + \frac{1}{3} [- (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2}] (1 - e^{2})^{3}$
	$=$	$- A_{s} (1 - e^{2}) + \frac{1}{2} [A_{s s} a_{ℓ}^{2} (1 - e^{2})^{2} + (1 - e^{2}) A_{s}] - \frac{1}{3} [(1 - e^{2})^{2} A_{s s} a_{ℓ}^{2}]$
	$=$	$- \frac{1}{2} [A_{s} (1 - e^{2})] + \frac{1}{6} [A_{s s} a_{ℓ}^{2} (1 - e^{2})^{2}]$

Hence, the central pressure is,

P_{c}^{*} \equiv [P_{d e d u c e d}^{*}]_{c e n t r a l} = C_{χ} |_{χ = 0}

=

$\frac{1}{2} [A_{s} (1 - e^{2})] - \frac{1}{6} [A_{s s} a_{ℓ}^{2} (1 - e^{2})^{2}] .$ [0.2045061]

For an oblate-spheroidal configuration having eccentricity, $e = 0.6 \Rightarrow a_{s} / a_{ℓ} = 0.8$ , the figure displayed here, on the right, shows how the normalized gas pressure $(P_{d e d u c e d}^{*} / P_{c}^{*})$ varies with height above the mid-plane $(ζ)$ at three different distances from the symmetry axis: (blue) $χ = 0.0$ , (orange) $χ = 0.6$ , and (gray) $χ = 0.75$ .

circular marker color	chosen $χ$	resulting …
circular marker color	chosen $χ$	surface $ζ$	mid-plane pressure
blue	$0.00$	$0.8000$	$1.00000$
orange	$0.60$	$0.6400$	$0.32667$
gray	$0.75$	$0.52915$	$0.13085$

Inserting the expression for $C_{λ}$ into our derived expression for $P_{d e d u c e d}^{*}$ gives,

P_{d e d u c e d}^{*}

=

$(c o e f 1) \cdot [ζ^{2} - (1 - e^{2}) (1 - χ^{2})] + (c o e f 2) \cdot [ζ^{4} - (1 - e^{2})^{2} (1 - χ^{2})^{2}] + (c o e f 3) \cdot [ζ^{6} - (1 - e^{2})^{3} (1 - χ^{2})^{3}] .$

Note for later use that,

\frac{\partial C_{χ}}{\partial χ}

=

…

Isobaric Surfaces[edit]

By design, the mass within our oblate-spheroidal configuration is distributed in such a way that iso-density surfaces are concentric spheroids. As stated earlier, the relevant mathematically prescribed density distribution is,

$\frac{ρ (χ, ζ)}{ρ_{c}}$

$=$

$[1 - χ^{2} - ζ^{2} (1 - e^{2})^{- 1}] .$

In order to determine the relative stability of each configuration, it will be important to ascertain whether or not isobaric surfaces are also concentric spheroids. (If they are, then we can say that each configuration obeys a barotropic — but not necessarily a polytropic — equation of state; see, for example, the accompanying relevant excerpt drawn from p. 466 of 📚 Lebovitz (1967).) In an effort to make this determination for our $e = 0.6$ spheroid, we first examine the iso-density surface for which $ρ / ρ_{c} = 0.3$ . Via the expression,

$ζ^{2}$

$=$

$(1 - e^{2}) [1 - χ^{2} - \frac{ρ}{ρ_{c}}] = 0.64 [1 - χ^{2} - 0.3],$

we can immediately determine that our three chosen radial cuts $(χ = 0.0, 0.6, 0.75)$ intersect this iso-density surface at the vertical locations, respectively, $ζ = 0.66933, 0.46648, 0.29665$ ; these numerical values have been recorded in the following table. The table also contains coordinates for the points where our three cuts intersect the $(e = 0.6)$ iso-density surface for which $ρ / ρ_{c} = 0.6$ .

diamond marker color	chosen $ρ / ρ_{c}$	chosen $χ$	resulting …
diamond marker color	chosen $ρ / ρ_{c}$	chosen $χ$	$ζ$	normalized pressure
green	$0.3$	$0.00$	$0.66933$	$0.060466$
		$0.60$	$0.46648$	$0.057433$
		$0.75$	$0.29665$	$0.055727$
purple	$0.6$	$0.00$	$0.50596$	$0.292493$
		$0.60$	$0.16000$	$0.280361$
		$0.75$	n/a	n/a

For each of these five $(χ, ζ)$ coordinate pairs, we have used our above derived expression for $P_{d e d u c e d}^{*} / P_{c}^{*}$ to calculate the "normalized pressure" at the relevant point inside the configuration. These results appear in the last column of the table; they also have been marked in the accompanying figure: dark green diamonds mark the points relevant to our choice of $ρ / ρ_{c} = 0.3$ and purple diamonds mark the points relevant to our choice of $ρ / ρ_{c} = 0.6$ . Notice that the normalized density is everywhere lower than $0.6$ along the $χ = 0.75$ cut, so the final row in the table has been marked "n/a" (not applicable).

The dark green diamond-shaped markers in the figure — along with the associated tabular data — show that at three separate points along the $ρ / ρ_{c} = 0.3$ iso-density surface, the normalized pressure is nearly — but not exactly — the same; its value is approximately $0.057$ . Similarly, the purple diamond-shaped markers show that at two separate points along the $ρ / ρ_{c} = 0.6$ iso-density surface, the normalized pressure is nearly the same; in this case its value is approximately $0.28$ . This seems to indicate that, throughout our configuration, the isobaric surfaces are almost — but not exactly — aligned with iso-density surfaces.

Now Play With Radial Pressure Gradient[edit]

After multiplying through by $ρ / ρ_{c}$ , the last term on the RHS of the ${\hat{e}}_{ϖ}$ component is given by the expression,

$\frac{ρ}{ρ_{c}} \cdot [\frac{1}{(- π G ρ_{c} a_{ℓ}^{2})}] \frac{\partial Φ_{g r a v}}{\partial χ}$	$=$	$2 [1 - χ^{2} - ζ^{2} (1 - e^{2})^{- 1}] [(A_{ℓ s} a_{ℓ}^{2} ζ^{2} - A_{ℓ}) χ + A_{ℓ ℓ} a_{ℓ}^{2} χ^{3}]$
	$=$	$2 [(A_{ℓ s} a_{ℓ}^{2} ζ^{2} - A_{ℓ}) χ + A_{ℓ ℓ} a_{ℓ}^{2} χ^{3}] - 2 χ^{2} [(A_{ℓ s} a_{ℓ}^{2} ζ^{2} - A_{ℓ}) χ + A_{ℓ ℓ} a_{ℓ}^{2} χ^{3}] - 2 ζ^{2} (1 - e^{2})^{- 1} [(A_{ℓ s} a_{ℓ}^{2} ζ^{2} - A_{ℓ}) χ + A_{ℓ ℓ} a_{ℓ}^{2} χ^{3}]$
	$=$	$2 (A_{ℓ s} a_{ℓ}^{2} ζ^{2} - A_{ℓ}) χ + 2 [A_{ℓ ℓ} a_{ℓ}^{2} + (A_{ℓ} - A_{ℓ s} a_{ℓ}^{2} ζ^{2})] χ^{3} - 2 A_{ℓ ℓ} a_{ℓ}^{2} χ^{5} + 2 (1 - e^{2})^{- 1} [(A_{ℓ} ζ^{2} - A_{ℓ s} a_{ℓ}^{2} ζ^{4}) χ - A_{ℓ ℓ} a_{ℓ}^{2} ζ^{2} χ^{3}]$
	$=$	$2 [(A_{ℓ s} a_{ℓ}^{2} ζ^{2} - A_{ℓ}) + (1 - e^{2})^{- 1} (A_{ℓ} ζ^{2} - A_{ℓ s} a_{ℓ}^{2} ζ^{4})] χ + 2 [A_{ℓ ℓ} a_{ℓ}^{2} + (A_{ℓ} - A_{ℓ s} a_{ℓ}^{2} ζ^{2}) - (1 - e^{2})^{- 1} A_{ℓ ℓ} a_{ℓ}^{2} ζ^{2}] χ^{3} - 2 A_{ℓ ℓ} a_{ℓ}^{2} χ^{5} .$

If we replace the normalized pressure by $P_{d e d u c e d}^{*}$ , the first term on the RHS of the ${\hat{e}}_{ϖ}$ component becomes,

$\frac{\partial P_{d e d u c e d}^{*}}{\partial χ}$	$=$	$\frac{\partial}{\partial χ} {[- A_{s} ζ^{2} + \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} + \frac{1}{2} (1 - e^{2})^{- 1} A_{s} ζ^{4} - \frac{1}{3} (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2} ζ^{6}] χ^{0} + [A_{ℓ s} a_{ℓ}^{2} ζ^{2} + A_{s} ζ^{2} - \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} - \frac{1}{2} (1 - e^{2})^{- 1} (A_{ℓ s} a_{ℓ}^{2} ζ^{4})] χ^{2} + [- A_{ℓ s} a_{ℓ}^{2} ζ^{2}] χ^{4} + P_{c}^{*}}$
	$=$	$2 [A_{ℓ s} a_{ℓ}^{2} ζ^{2} + A_{s} ζ^{2} - \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} - \frac{1}{2} (1 - e^{2})^{- 1} (A_{ℓ s} a_{ℓ}^{2} ζ^{4})] χ + 4 [- A_{ℓ s} a_{ℓ}^{2} ζ^{2}] χ^{3}$

Hence,

$\frac{1}{χ^{3}} \cdot \frac{j^{2}}{(π G ρ_{c} a_{ℓ}^{4})} \cdot \frac{ρ}{ρ_{c}}$

=

$[\frac{\partial P_{d e d u c e d}^{*}}{\partial χ}] - \frac{ρ}{ρ_{c}} \cdot \frac{\partial}{\partial χ} [\frac{Φ_{g r a v}}{(- π G ρ_{c} a_{ℓ}^{2})}]$

10^th Try[edit]

Repeating Key Relations[edit]

Density:	$\frac{ρ (ϖ, z)}{ρ_{c}}$	$=$	$[1 - χ^{2} - ζ^{2} (1 - e^{2})^{- 1}],$
Gravitational Potential:	$\frac{Φ_{g r a v} (ϖ, z)}{(- π G ρ_{c} a_{ℓ}^{2})}$	$=$	$\frac{1}{2} I_{B T} - A_{ℓ} χ^{2} - A_{s} ζ^{2} + \frac{1}{2} [(A_{s s} a_{ℓ}^{2}) ζ^{4} + 2 (A_{ℓ s} a_{ℓ}^{2}) χ^{2} ζ^{2} + (A_{ℓ ℓ} a_{ℓ}^{2}) χ^{4}] .$
Vertical Pressure Gradient:	$[\frac{1}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] \frac{\partial P}{\partial ζ}$	$=$	$\frac{ρ}{ρ_{c}} \cdot [2 A_{ℓ s} a_{ℓ}^{2} χ^{2} ζ - 2 A_{s} ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3}]$

From the above (9^th Try) examination of the vertical pressure gradient, we determined that a reasonably good approximation for the normalized pressure throughout the configuration is given by the expression,

[\frac{1}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] \int [\frac{\partial P}{\partial ζ}] d ζ

=

$[- A_{s} ζ^{2} + \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} + \frac{1}{2} (1 - e^{2})^{- 1} A_{s} ζ^{4} - \frac{1}{3} (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2} ζ^{6}] χ^{0} + [A_{ℓ s} a_{ℓ}^{2} ζ^{2} + A_{s} ζ^{2} - \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} - \frac{1}{2} (1 - e^{2})^{- 1} (A_{ℓ s} a_{ℓ}^{2} ζ^{4})] χ^{2} + [- A_{ℓ s} a_{ℓ}^{2} ζ^{2}] χ^{4} + c o n s t .$

If we set $χ = 0$ — that is, if we look along the vertical axis — this approximation should be particularly good, resulting in the expression,

P_{z} \equiv {[\frac{1}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] \int [\frac{\partial P}{\partial ζ}] d ζ}_{χ = 0}

=

$P_{c}^{*} - A_{s} ζ^{2} + \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} + \frac{1}{2} (1 - e^{2})^{- 1} A_{s} ζ^{4} - \frac{1}{3} (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2} ζ^{6} .$

Note that in the limit that $z \to a_{s}$ — that is, at the pole along the vertical (symmetry) axis where the $P_{z}$ should drop to zero — we should set $ζ \to (1 - e^{2})^{1 / 2}$ . This allows us to determine the central pressure.

$P_{c}^{*}$	$=$	$A_{s} (1 - e^{2}) - \frac{1}{2} A_{s s} a_{ℓ}^{2} (1 - e^{2})^{2} - \frac{1}{2} (1 - e^{2})^{- 1} A_{s} (1 - e^{2})^{2} + \frac{1}{3} (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2} (1 - e^{2})^{3}$
	$=$	$A_{s} (1 - e^{2}) - \frac{1}{2} A_{s} (1 - e^{2}) + \frac{1}{3} A_{s s} a_{ℓ}^{2} (1 - e^{2})^{2} - \frac{1}{2} A_{s s} a_{ℓ}^{2} (1 - e^{2})^{2}$
	$=$	$\frac{1}{2} A_{s} (1 - e^{2}) - \frac{1}{6} A_{s s} a_{ℓ}^{2} (1 - e^{2})^{2} .$

This means that, along the vertical axis, the pressure gradient is,

P_{z} \equiv {[\frac{1}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] \int [\frac{\partial P}{\partial ζ}] d ζ}_{χ = 0}

=

$P_{c}^{*} - A_{s} ζ^{2} + \frac{1}{2} A_{s s} a_{ℓ}^{2} ζ^{4} + \frac{1}{2} (1 - e^{2})^{- 1} A_{s} ζ^{4} - \frac{1}{3} (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2} ζ^{6} .$

\frac{\partial P_{z}}{\partial ζ}

=

$- 2 A_{s} ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3} + 2 (1 - e^{2})^{- 1} A_{s} ζ^{3} - 2 (1 - e^{2})^{- 1} A_{s s} a_{ℓ}^{2} ζ^{5} .$

This should match the more general "vertical pressure gradient" expression when we set, $χ = 0$ , that is,

${[\frac{1}{(π G ρ_{c}^{2} a_{ℓ}^{2})}] \frac{\partial P}{\partial ζ}}_{χ = 0}$	$=$	$[1 - {χ^{2}}^{0} - ζ^{2} (1 - e^{2})^{- 1}] \cdot [2 A_{ℓ s} a_{ℓ}^{2} ζ {χ^{2}}^{0} - 2 A_{s} ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3}]$
	$=$	$[- 2 A_{s} ζ + 2 A_{s s} a_{ℓ}^{2} ζ^{3}] + ζ^{2} (1 - e^{2})^{- 1} [2 A_{s} ζ - 2 A_{s s} a_{ℓ}^{2} ζ^{3}]$

Yes! The expressions match!

ParabolicDensity/Axisymmetric/Structure: Difference between revisions

Latest revision as of 15:36, 16 November 2024

Contents

Parabolic Density Distribution[edit]

Axisymmetric (Oblate) Equilibrium Structures[edit]

Tentative Summary[edit]

Known Relations[edit]

Play With Vertical Pressure Gradient[edit]

Isobaric Surfaces[edit]

Now Play With Radial Pressure Gradient[edit]

10^th Try[edit]

Repeating Key Relations[edit]

See Also[edit]

Navigation menu

@@ Line 11: / Line 11: @@
    </td>
    <td align="center" bgcolor="lightblue" width="25%"><br />[[ParabolicDensity/Axisymmetric/Structure|Part III: &nbsp; Axisymmetric Equilibrium Structures]]
-&nbsp;
+&nbsp;[[ParabolicDensity/Axisymmetric/Structure/Try1thru7|Old: 1<sup>st</sup> thru 7<sup>th</sup> tries]]<br />
+&nbsp;[[ParabolicDensity/Axisymmetric/Structure/Try8thru10|Old: 8<sup>th</sup> thru 10<sup>th</sup> tries]]
    </td>
    <td align="center" bgcolor="lightblue"><br />[[ParabolicDensity/Triaxial/Structure|Part IV: &nbsp; Triaxial Equilibrium Structures (Exploration)]]
@@ Line 20: / Line 21: @@
 ==Axisymmetric (Oblate) Equilibrium Structures==
-Here we specifically discuss the case of configurations that exhibit concentric ellipsoidal iso-density surfaces of the form,
+===Tentative Summary===
+====Known Relations====
 <table border="0" cellpadding="5" align="center">
 <tr>
+  <td align="left"><font color="orange"><b>Density:</b></font></td>
    <td align="right">
-<math>\rho</math>
+<math>\frac{\rho(\varpi, z)}{\rho_c}</math>
    </td>
    <td align="center">
-=
+<math>=</math>
    </td>
    <td align="left">
-<math>\rho_c \biggl[ 1 -  \biggl( \frac{x^2 + y^2}{a_\ell^2}  + \frac{z^2}{a_s^2}\biggr) \biggr] \, ,</math>
+<math>
+\biggl[1 - \chi^2 - \zeta^2(1-e^2)^{-1} \biggr]
+\, ,</math>
    </td>
 </tr>
-</table>
-that is, axisymmetric (<math> a_m = a_\ell</math>, i.e., oblate) configurations with ''parabolic density distributions''.  Much of our presentation, here, is drawn from our separate, detailed description of what we will refer to as [[ThreeDimensionalConfigurations/FerrersPotential|Ferrers potential]].
-===Gravitational Potential===
-As we have detailed in [[ThreeDimensionalConfigurations/FerrersPotential|an accompanying discussion]], for an oblate-spheroidal configuration &#8212; that is, when <math>a_s < a_m = a_\ell</math> &#8212; the gravitational potential may be obtained from the expression,
-<table border="0" cellpadding="5" align="center">
 <tr>
+  <td align="left"><font color="orange"><b>Gravitational Potential:</b></font></td>
    <td align="right">
-<math>\frac{ \Phi_\mathrm{grav}(\mathbf{x})}{(-\pi G\rho_c)}</math>
+<math>\frac{ \Phi_\mathrm{grav}(\varpi,z)}{(-\pi G\rho_c a_\ell^2)} </math>
    </td>
-   <td align="center"><math>=</math></td>
+   <td align="center">
-  <td align="left">
+<math>=</math>
-<math>
-\frac{1}{2} I_\mathrm{BT} a_1^2
-- \biggl(A_1 x^2 + A_2 y^2 +A_3 z^2 \biggr)
-+ \biggl( A_{12} x^2y^2 + A_{13} x^2z^2 + A_{23} y^2z^2\biggr)
-+ \frac{1}{6}  \biggl(3A_{11}x^4 +  3A_{22}y^4 + 3A_{33}z^4  \biggr)
-\, ,
-</math>
-  </td>
-</tr>
-</table>
-where, in the present context, we can rewrite this expression as,
-<table border="0" cellpadding="5" align="center">
-<tr>
-  <td align="right">
-<math>\frac{ \Phi_\mathrm{grav}(\mathbf{x})}{(-\pi G\rho_c)}</math>
    </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{2} I_\mathrm{BT} a_\ell^2
+\frac{1}{2} I_\mathrm{BT}
-- \biggl[A_\ell (x^2 + y^2) + A_s z^2 \biggr]
+- A_\ell \chi^2  - A_s \zeta^2
-+ \biggl[ A_{\ell \ell} x^2y^2 + A_{\ell s} x^2z^2 + A_{\ell s} y^2z^2\biggr]
+ + \frac{1}{2}\biggl[(A_{s s} a_\ell^2) \zeta^4
-+ \frac{1}{6}  \biggl[3A_{\ell \ell} x^4 +  3A_{\ell \ell}y^4 + 3A_{ss}z^4  \biggr]
++ 2(A_{\ell s}a_\ell^2 )\chi^2 \zeta^2
++ (A_{\ell \ell} a_\ell^2)  \chi^4 \biggr]
+\, .
 </math>
    </td>
@@ Line 79: / Line 64: @@
 <tr>
+  <td align="left">&nbsp;</td>
    <td align="right">
-&nbsp;
+<math>\Rightarrow ~~~ \frac{\partial}{\partial\zeta} \biggl[\frac{ \Phi_\mathrm{grav}}{(-\pi G\rho_c a_\ell^2)} \biggr]</math>
    </td>
-   <td align="center"><math>=</math></td>
+   <td align="center">
-  <td align="left">
+<math>=</math>
-<math>
-\frac{1}{2} I_\mathrm{BT} a_\ell^2
-- \biggl[A_\ell \varpi^2 + A_s z^2 \biggr]
-+ \biggl[ A_{\ell \ell} x^2y^2 + A_{\ell s} \varpi^2 z^2 \biggr]
-+ \frac{1}{2}  \biggl[A_{\ell \ell} (x^4 + y^4) + A_{ss}z^4  \biggr]
-</math>
-  </td>
-</tr>
-<tr>
-  <td align="right">
-&nbsp;
    </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{2} I_\mathrm{BT} a_\ell^2
+(A_{\ell s}a_\ell^2 )\chi^2 \zeta - 2A_s \zeta  + 2(A_{s s} a_\ell^2) \zeta^3
-- \biggl[A_\ell \varpi^2 + A_s z^2 \biggr]
+\, .
-+ \frac{A_{\ell \ell}}{2}  \biggl[(x^2 + y^2)^2\biggr]
-+ \frac{1}{2}  \biggl[ A_{ss}z^4  \biggr]
-+ \biggl[ A_{\ell s} \varpi^2 z^2 \biggr]
 </math>
    </td>
@@ Line 110: / Line 80: @@
 <tr>
+  <td align="left">&nbsp;</td>
    <td align="right">
-&nbsp;
+and, &nbsp; &nbsp; <math>\frac{\partial}{\partial\chi} \biggl[\frac{ \Phi_\mathrm{grav}}{(-\pi G\rho_c a_\ell^2)} \biggr]</math>
    </td>
-   <td align="center"><math>=</math></td>
+   <td align="center">
-  <td align="left">
+<math>=</math>
-<math>
-\frac{1}{2} I_\mathrm{BT} a_\ell^2
-- \biggl[A_\ell \varpi^2 + A_s z^2 \biggr]
-+ \frac{A_{\ell \ell}}{2}  \biggl[\varpi^4\biggr]
-+ \frac{1}{2}  \biggl[ A_{ss}z^4  \biggr]
-+ \biggl[ A_{\ell s} \varpi^2 z^2 \biggr]
-</math>
    </td>
-</tr>
-<tr>
-  <td align="right">
-<math>\Rightarrow ~~~ \frac{ \Phi_\mathrm{grav}(\mathbf{x})}{(-\pi G\rho_c a_\ell^2)}</math>
-  </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{2} I_\mathrm{BT}
+(A_{\ell s}a_\ell^2 )\chi \zeta^2
-- \biggl[A_\ell \biggl(\frac{\varpi^2}{a_\ell^2}\biggr) + A_s \biggl( \frac{z^2}{a_\ell^2}\biggr) \biggr]
+- 2A_\ell \chi
-+ \frac{1}{2} \biggl[
++ 2(A_{\ell \ell} a_\ell^2)  \chi^3
-A_{\ell \ell} a_\ell^2  \biggl(\frac{\varpi^4}{a_\ell^4}\biggr)
-+ A_{ss} a_\ell^2  \biggl(\frac{z^4}{a_\ell^4}\biggr)
-+ 2A_{\ell s}a_\ell^2 \biggl( \frac{\varpi^2 z^2}{a_\ell^4}\biggr)
-\biggr]
 \, .
 </math>
@@ Line 145: / Line 98: @@
 </table>
-====Index Symbol Expressions====
+where, <math>\chi \equiv \varpi/a_\ell</math> and <math>\zeta \equiv z/a_\ell</math>, and the relevant index symbol expressions are:
-The expression for the zeroth-order normalization term <math>(I_{BT})</math>, and the relevant pair of 1<sup>st</sup>-order index symbol expressions are:
 <table align="center" border=0 cellpadding="3">
@@ Line 158: / Line 110: @@
 </math>
    </td>
+  <td align="right">[1.7160030]</td>
 </tr>
@@ Line 176: / Line 129: @@
 </math>
    </td>
+  <td align="right">[0.6055597]</td>
 </tr>
@@ Line 183: / Line 137: @@
    <td align="left">
 <math>
-\frac{2}{e^2} \biggl[  (1-e^2)^{-1/2} - \frac{\sin^{-1}e}{e} \biggr] (1-e^2)^{1 / 2} \, ,
+\frac{2}{e^2} \biggl[  (1-e^2)^{-1/2} - \frac{\sin^{-1}e}{e} \biggr] (1-e^2)^{1 / 2} \, ;
 </math>
    </td>
+  <td align="right">[0.7888807]</td>
 </tr>
-</table>
-<div align="center">
-[<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>], <font color="#00CC00">Chapter 3, Eq. (36)</font><br />
-[<b>[[Appendix/References#T78|<font color="red">T78</font>]]</b>], <font color="#00CC00">&sect;4.5, Eqs. (48) &amp; (49)</font>
-</div>
-where the eccentricity,
-<div align="center">
-<math>
-e \equiv \biggl[1 - \biggl(\frac{a_s}{a_\ell}\biggr)^2  \biggr]^{1 / 2} \, .
-</math>
-</div>
-The relevant [[ThreeDimensionalConfigurations/HomogeneousEllipsoids#Index_Symbols_of_the_2nd_Order|2<sup>nd</sup>-order index symbol]] expressions are:
-<table align="center" border=0 cellpadding="3">
 <tr>
@@ Line 219: / Line 157: @@
 <math>
 \frac{1}{4e^4}\biggl\{- (3 + 2e^2) (1-e^2)+3 (1 - e^2)^{1 / 2} \biggl[\frac{\sin^{-1}e}{e}\biggr] \biggr\}
+=
+\biggl[\frac{1}{2}-\frac{(A_s - A_\ell)}{4e^2}\biggr]
 \, ;
-</math>
+</math>&nbsp; &nbsp; &nbsp; &nbsp;
    </td>
+  <td align="right">[0.3726937]</td>
 </tr>
 <tr>
    <td align="right">
-<math>\frac{3}{2} a_\ell^2 A_{ss} </math>
+<math>a_\ell^2 A_{ss} </math>
    </td>
    <td align="center">
@@ Line 232: / Line 173: @@
    </td>
    <td align="left">
-<math>
+<math>\frac{2}{3}\biggl\{
 \frac{( 4e^2 - 3 )}{e^4(1-e^2)}
 +
-\frac{3 (1-e^2)^{1 / 2}}{e^4} \biggl[\frac{\sin^{-1}e}{e}\biggr]
+\frac{3 (1-e^2)^{1 / 2}}{e^4} \biggl[\frac{\sin^{-1}e}{e}\biggr] \biggr\}
+=
+\frac{2}{3}\biggl[ (1-e^2)^{-1} - \frac{(A_s-A_\ell)}{e^2} \biggr]
 \, ;
-</math>
+</math>&nbsp; &nbsp; &nbsp; &nbsp;
    </td>
+  <td align="right">[0.7021833]</td>
 </tr>
@@ Line 258: / Line 202: @@
 -
 (1-e^2)^{1 / 2} \biggl[\frac{\sin^{-1}e}{e}\biggr]
-\biggr\} \, .
+\biggr\}
+=
+\frac{(A_s - A_\ell)}{e^2}
+\, ,
 </math>
    </td>
+  <td align="right">[0.5092250]</td>
 </tr>
 </table>
-We can crosscheck this last expression by [[ParabolicDensity/GravPot#Parabolic_Density_Distribution_2|drawing on a shortcut expression]],
+where the eccentricity,
+<div align="center">
+<math>
+e \equiv \biggl[1 - \biggl(\frac{a_s}{a_\ell}\biggr)^2  \biggr]^{1 / 2} \, .
+</math>
+</div>
+<font color="red">NOTE: &nbsp; The posted numerical evaluations (inside square brackets) assume that the configuration's eccentricity is</font> <math>e = 0.6 \Rightarrow a_s/a_\ell = 0.8</math>.
+Drawing from our separate "[[ParabolicDensity/Axisymmetric/Structure/Try8thru10#6th_Try|6<sup>th</sup> Try]]" discussion &#8212; and as has been highlighted [[AxisymmetricConfigurations/PGE#RelevantCylindricalComponents|here]] for example &#8212; for the axisymmetric configurations under consideration, the <math>\hat{e}_z</math> and <math>\hat{e}_\varpi</math> components of the Euler equation become, respectively,</span>
+<table border="1" align="center" cellpadding="10"><tr><td align="center">
 <table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math>{\hat{e}}_z</math>: &nbsp; &nbsp;</td>
+  <td align="right">
+<math>
+</math>
+  </td>
+  <td align="center">
+=
+  </td>
+  <td align="left">
+<math>
+\biggl[ \frac{1}{\rho}\frac{\partial P}{\partial z} + \frac{\partial \Phi}{\partial z} \biggr]
+</math>
+  </td>
+</tr>
 <tr>
+  <td align="right"><math>{\hat{e}}_\varpi</math>: &nbsp; &nbsp;</td>
    <td align="right">
-<math>A_{\ell s}</math>
+<math>
+\frac{j^2}{\varpi^3}
+</math>
+  </td>
+  <td align="center">
+=
    </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-- \frac{A_\ell - A_s}{(a_\ell^2 - a_s^2)}
+\biggl[ \frac{1}{\rho}\frac{\partial P}{\partial\varpi} + \frac{\partial \Phi}{\partial\varpi}\biggr]
 </math>
    </td>
 </tr>
+</table>
+</td></tr></table>
+Multiplying the <math>\hat{e}_z</math> component through by length <math>(a_\ell)</math> and dividing through by the square of the velocity <math>(\pi G \rho_c a_\ell^2)</math>, we have,
+<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>\Rightarrow ~~~ a_\ell^2 A_{\ell s}</math>
+<math>
+</math>
+  </td>
+  <td align="center">
+=
    </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{e^2}\biggl\{
+\biggl[ \frac{1}{\rho}\frac{\partial P}{\partial z} + \frac{\partial \Phi}{\partial z} \biggr]\frac{a_\ell}{(\pi G\rho_c a_\ell^2)}
-A_s - A_\ell
-\biggr\}
 </math>
    </td>
@@ Line 296: / Line 283: @@
 &nbsp;
    </td>
-   <td align="center"><math>=</math></td>
+   <td align="center">
+=
+  </td>
    <td align="left">
 <math>
-\frac{1}{e^2}\biggl\{
+\frac{\rho_c}{\rho}\cdot \frac{\partial }{\partial \zeta}\biggl[ \frac{P}{(\pi G\rho_c^2 a_\ell^2)} \biggr]
-\frac{2}{e^2} \biggl[  (1-e^2)^{-1/2} - \frac{\sin^{-1}e}{e} \biggr] (1-e^2)^{1 / 2}
+- \frac{\partial }{\partial \zeta}\biggl[ \frac{\Phi}{(-~\pi G\rho_c a_\ell^2)} \biggr]
--
-\frac{1}{e^2} \biggl[  \frac{\sin^{-1}e}{e} - (1-e^2)^{1/2} \biggr] (1-e^2)^{1/2}
-\biggr\}
 </math>
    </td>
@@ Line 310: / Line 296: @@
 <tr>
    <td align="right">
-&nbsp;
+<math>\Rightarrow ~~~ \frac{\partial }{\partial \zeta}\biggl[ \frac{P}{(\pi G\rho_c^2 a_\ell^2)} \biggr] </math>
+  </td>
+  <td align="center">
+=
    </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{e^4}\biggl\{
+\frac{\rho}{\rho_c}\cdot \frac{\partial }{\partial \zeta}\biggl[ \frac{\Phi}{(-~\pi G\rho_c a_\ell^2)} \biggr]
-\biggl[ 2 -  2(1-e^2)^{1 / 2} \frac{\sin^{-1}e}{e} \biggr]
--
-\biggl[ (1-e^2)^{1/2} \frac{\sin^{-1}e}{e} - (1-e^2) \biggr]
-\biggr\}
 </math>
    </td>
@@ Line 328: / Line 312: @@
 &nbsp;
    </td>
-   <td align="center"><math>=</math></td>
+   <td align="center">
+=
+  </td>
    <td align="left">
 <math>
-\frac{1}{e^4}\biggl\{(3-e^2) -  3(1-e^2)^{1 / 2} \frac{\sin^{-1}e}{e}  \biggr\}
+\frac{\rho}{\rho_c}\cdot \biggl[
-\, .
+(A_{\ell s}a_\ell^2 )\chi^2 \zeta - 2A_s \zeta  + 2(A_{s s} a_\ell^2) \zeta^3
+\biggr]
 </math>
    </td>
@@ Line 338: / Line 325: @@
 </table>
-====Meridional Plane Equi-Potential Contours====
+Multiplying the <math>\hat{e}_\varpi</math> component through by length <math>(a_\ell)</math> and dividing through by the square of the velocity <math>(\pi G \rho_c a_\ell^2)</math>, we have,
-Here, we follow closely our separate discussion of equipotential surfaces for [[Apps/MaclaurinSpheroids#norotation|Maclaurin Spheroids, assuming no rotation]].
-In the meridional <math>(\varpi, z)</math> plane, the surface of this oblate-spheroidal configuration &#8212; identified by the thick, solid-black curve below, in Figure 1 &#8212; is defined by the expression,
 <table border="0" cellpadding="5" align="center">
 <tr>
+  <td align="right"><math>{\hat{e}}_\varpi</math>: &nbsp; &nbsp;</td>
    <td align="right">
-<math>\frac{\rho}{\rho_c} </math>
+<math>
+\frac{j^2}{\varpi^3} \cdot \frac{a_\ell}{(\pi G\rho_c a_\ell^2)}
+</math>
    </td>
    <td align="center">
-<math>=</math>
+=
    </td>
-   <td align="left" colspan="2">
+   <td align="left">
-<math>1 - \biggl[\frac{\varpi^2}{a_\ell^2} + \frac{z^2}{a_s^2} \biggr] = 0</math>
+<math>
+\biggl[ \frac{1}{\rho}\frac{\partial P}{\partial\varpi} + \frac{\partial \Phi_\mathrm{grav}}{\partial\varpi}\biggr] \frac{a_\ell}{(\pi G\rho_c a_\ell^2)}
+</math>
    </td>
 </tr>
 <tr>
+  <td align="right">&nbsp;</td>
    <td align="right">
-<math>\Rightarrow ~~~ \frac{\varpi^2}{a_\ell^2} + \frac{z^2}{a_s^2}</math>
+<math>\Rightarrow ~~~
+\frac{1}{\chi^3} \cdot \frac{j^2}{(\pi G\rho_c a_\ell^4)}
+</math>
    </td>
    <td align="center">
-<math>=</math>
+=
    </td>
-   <td align="left" colspan="2">
+   <td align="left">
-<math>1 </math>
+<math>
+\frac{\rho_c}{\rho}\cdot\frac{\partial }{\partial \chi}\biggl[ \frac{P}{(\pi G\rho_c^2 a_\ell^2)} \biggr]
+- \frac{\partial }{\partial \chi}\biggl[ \frac{\Phi_\mathrm{grav}}{(-~\pi G\rho_c a_\ell^2)} \biggr]
+</math>
    </td>
 </tr>
+</table>
+====Play With Vertical Pressure Gradient====
+<table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>\biggl[\frac{1}{(\pi G\rho_c^2 a_\ell^2)} \biggr] \frac{\partial P}{\partial \zeta}</math></td>
-<math>\Rightarrow ~~~ z^2</math>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl[1 - \chi^2 - \zeta^2(1-e^2)^{-1} \biggr] \biggl[
+A_{\ell s}a_\ell^2 \chi^2\zeta - 2A_s \zeta
++  2A_{ss} a_\ell^2  \zeta^3
+\biggr]
+</math>
    </td>
-   <td align="center">
+</tr>
-<math>=</math>
+<tr>
+  <td align="right">&nbsp;</td>
+   <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl[ (2A_{\ell s}a_\ell^2 \chi^2 - 2A_s )\zeta  +  2A_{ss} a_\ell^2  \zeta^3   \biggr]
+- \chi^2 \biggl[ (2A_{\ell s}a_\ell^2 \chi^2 - 2A_s )\zeta  +  2A_{ss} a_\ell^2  \zeta^3   \biggr]
+- \zeta^2(1-e^2)^{-1}\biggl[ (2A_{\ell s}a_\ell^2 \chi^2 - 2A_s )\zeta  +  2A_{ss} a_\ell^2  \zeta^3   \biggr]
+</math>
    </td>
-   <td align="left" colspan="2">
+</tr>
-<math>a_s^2\biggl[1 - \frac{\varpi^2}{a_\ell^2} \biggr] = a_\ell^2 (1-e^2) \biggl[1 - \frac{\varpi^2}{a_\ell^2} \biggr]</math>
+<tr>
+   <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+(2A_{\ell s}a_\ell^2 \chi^2 - 2A_s )\zeta  +  2A_{ss} a_\ell^2  \zeta^3
+- (2A_{\ell s}a_\ell^2 \chi^4 - 2A_s \chi^2)\zeta  -  2A_{ss} a_\ell^2 \chi^2 \zeta^3
+- (1-e^2)^{-1}\biggl[ (2A_{\ell s}a_\ell^2 \chi^2 - 2A_s )\zeta^3  +  2A_{ss} a_\ell^2  \zeta^5   \biggr]
+</math>
    </td>
 </tr>
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-<math>\Rightarrow ~~~ \frac{z}{a_\ell}</math>
+   <td align="center"><math>=</math></td>
-  </td>
-   <td align="center">
-<math>=</math>
-  </td>
    <td align="left">
-<math>\pm ~(1-e^2)^{1 / 2} \biggl[1 - \frac{\varpi^2}{a_\ell^2} \biggr]^{1 / 2}  \, ,</math>
+<math>
+\biggl[ (2A_{\ell s}a_\ell^2 \chi^2 - 2A_s ) - (2A_{\ell s}a_\ell^2 \chi^4 - 2A_s \chi^2)\biggr]\zeta
++  \biggl[ 2A_{ss} a_\ell^2  -  2A_{ss} a_\ell^2 \chi^2 - (1-e^2)^{-1}(2A_{\ell s}a_\ell^2 \chi^2 - 2A_s )\biggr]\zeta^3
++ \biggl[ - (1-e^2)^{-1}2A_{ss} a_\ell^2 \biggr] \zeta^5
+\, .
+</math>
    </td>
-  <td align="right">&nbsp; &nbsp; &nbsp; &nbsp; for <math>~0 \le \frac{| \varpi |}{a_\ell} \le 1 \, .</math></td>
 </tr>
 </table>
-Throughout the interior of this configuration, each associated <math>~\Phi_\mathrm{eff}</math> = constant, equipotential surface is defined by the expression,
+Integrate over <math>\zeta</math> gives &hellip;
-<!--
 <table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>P^*_\mathrm{deduced} \equiv \biggl[\frac{1}{(\pi G\rho_c^2 a_\ell^2)} \biggr] \int \biggl[\frac{\partial P}{\partial \zeta}\biggr] d\zeta </math></td>
-<math>\phi_\mathrm{choice} \equiv \frac{\Phi_\mathrm{eff}}{\pi G \rho} +  I_\mathrm{BT}a_1^2 </math>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\overbrace{\biggl[ (A_{\ell s}a_\ell^2 \chi^2 - A_s ) - (A_{\ell s}a_\ell^2 \chi^4 - A_s \chi^2)\biggr]}^\mathrm{coef1}\zeta^2
++  \underbrace{\frac{1}{2}\biggl[ A_{ss} a_\ell^2  -  A_{ss} a_\ell^2 \chi^2 - (1-e^2)^{-1}(A_{\ell s}a_\ell^2 \chi^2 - A_s )\biggr]}_\mathrm{coef2}\zeta^4
++  \overbrace{\frac{1}{3}\biggl[ - (1-e^2)^{-1}A_{ss} a_\ell^2 \biggr]}^\mathrm{coef3} \zeta^6 + ~\mathrm{const}
+</math>
    </td>
-   <td align="center">
+</tr>
-<math>=</math>
-  </td>
+<tr>
-   <td align="left" colspan="1">
+  <td align="right">&nbsp;</td>
-<math>\biggl( A_1 - \frac{\omega_0^2}{2\pi G \rho}\biggr) \varpi^2 + A_3 z^2   </math>
+   <td align="center"><math>=</math></td>
+   <td align="left">
+<math>
+\biggl[-A_s \zeta^2 + \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 + \frac{1}{2}(1-e^2)^{-1}A_s\zeta^4 - \frac{1}{3}(1-e^2)^{-1}A_{ss} a_\ell^2  \zeta^6 \biggr]\chi^0
++ \biggl[ A_{\ell s}a_\ell^2 \zeta^2 + A_s\zeta^2
+- \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 - \frac{1}{2}(1-e^2)^{-1}(A_{\ell s}a_\ell^2 \zeta^4 )
+\biggr]\chi^2
++  \biggl[- A_{\ell s}a_\ell^2 \zeta^2 \biggr]\chi^4 + ~\mathrm{const.}
+</math>
    </td>
 </tr>
 </table>
--->
+<!-- NOTE:  &nbsp; The integration constant must be the dimensionless central pressure, <math>P_c^*</math>. -->
+If I am interpreting this correctly, <math>P_\mathrm{deduced}^*</math> should tell how the normalized pressure varies with <math>\zeta</math>, for a fixed choice of <math>0 \le \chi \le 1</math>.  Again, for a fixed choice of <math>\chi</math>, we want to specify the value of the "const." &#8212; hereafter, <math>C_\chi</math> &#8212; such that <math>P_\mathrm{deduced}^* = 0</math> at the surface of the configuration; but at the surface where <math>\rho/\rho_c = 0</math>, it must also be true that,
 <table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right">at the surface &nbsp; &hellip; &nbsp;</td>
-<math>\phi_\mathrm{choice} \equiv \frac{ \Phi_\mathrm{grav}(\mathbf{x})}{(\pi G\rho_c a_\ell^2)} + \frac{1}{2} I_\mathrm{BT}
+  <td align="right"><math>\zeta^2</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+(1-e^2)\biggl[ 1 - \chi^2 - \cancelto{0}{\frac{\rho}{\rho_c}} \biggr]
+= (1-e^2)(1-\chi^2)
+\, .
 </math>
    </td>
+</tr>
+</table>
+Hence <font color="red">(numerical evaluations assume &chi; = 0.6 as well as e = 0.6)</font>,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math>-~C_\chi</math></td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\biggl[A_\ell \biggl(\frac{\varpi^2}{a_\ell^2}\biggr) + A_s \biggl( \frac{z^2}{a_\ell^2}\biggr) \biggr]
+\overbrace{\biggl[ (A_{\ell s}a_\ell^2 \chi^2 - A_s ) - (A_{\ell s}a_\ell^2 \chi^4 - A_s \chi^2)\biggr]}^{\mathrm{coef1} ~=~ -0.38756}\biggl[ (1-e^2)( 1 - \chi^2 )  \biggr]
-- \frac{1}{2} \biggl[
++  \underbrace{\frac{1}{2}\biggl[ A_{ss} a_\ell^2  -  A_{ss} a_\ell^2 \chi^2 - (1-e^2)^{-1}(A_{\ell s}a_\ell^2 \chi^2 - A_s )\biggr]}_{\mathrm{coef2} ~=~ 0.69779}\biggl[ (1-e^2)( 1 - \chi^2 )  \biggr]^2
-A_{\ell \ell} a_\ell^2  \biggl(\frac{\varpi^4}{a_\ell^4}\biggr)
++ \overbrace{\frac{1}{3}\biggl[ - (1-e^2)^{-1}A_{ss} a_\ell^2 \biggr]}^{\mathrm{coef3} ~=~ -0.36572} \biggl[ (1-e^2)( 1 - \chi^2 )  \biggr]^3
-+ A_{ss} a_\ell^2  \biggl(\frac{z^4}{a_\ell^4}\biggr)
+= -~0.66807 \, .
-+ 2A_{\ell s}a_\ell^2 \biggl( \frac{\varpi^2 z^2}{a_\ell^4}\biggr)
-\biggr]
-\, .
 </math>
    </td>
 </tr>
 </table>
+<table border="1" align="center" width="80%" cellpadding="8"><tr><td align="left">
+<div align="center">'''Central Pressure'''</div>
-Letting,
+At the center of the configuration &#8212; where <math>\zeta = \chi = 0</math> &#8212; we see that,
-<div align="center"><math>\zeta \equiv \frac{z^2}{a_\ell^2}</math>,</div>
-we can rewrite this expression for <math>\phi_\mathrm{choice}</math> as,
 <table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>-~C_\chi\biggr|_{\chi=0}</math></td>
-<math>\phi_\mathrm{choice} </math>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl[ ( - A_s )  \biggr](1-e^2)
++  \frac{1}{2}\biggl[ A_{ss} a_\ell^2  + (1-e^2)^{-1} A_s \biggr](1-e^2)^2
++ \frac{1}{3}\biggl[ - (1-e^2)^{-1}A_{ss} a_\ell^2 \biggr] (1-e^2)^3
+</math>
    </td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-A_\ell \biggl(\frac{\varpi^2}{a_\ell^2}\biggr) + A_s \zeta
+- A_s (1-e^2)
-- \frac{1}{2} A_{\ell \ell} a_\ell^2  \biggl(\frac{\varpi^4}{a_\ell^4}\biggr)
++  \frac{1}{2}\biggl[ A_{ss} a_\ell^2(1-e^2)^2  + (1-e^2)A_s \biggr]
-- \frac{1}{2}  A_{ss} a_\ell^2  \zeta^2
+- \frac{1}{3}\biggl[ (1-e^2)^{2}A_{ss} a_\ell^2 \biggr]
-- A_{\ell s}a_\ell^2 \biggl( \frac{\varpi^2 }{a_\ell^2}\biggr)\zeta
 </math>
    </td>
@@ Line 455: / Line 517: @@
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-&nbsp;
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+- \frac{1}{2}\biggl[ A_s (1-e^2) \biggr]
++  \frac{1}{6}\biggl[ A_{ss} a_\ell^2(1-e^2)^2  \biggr]
+</math>
    </td>
+</tr>
+</table>
+Hence, the central pressure is,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math>P^*_c \equiv \biggl[P^*_\mathrm{deduced}\biggr]_\mathrm{central} = C_\chi\biggr|_{\chi=0}</math></td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-- \frac{1}{2}  A_{ss} a_\ell^2  \zeta^2
+\frac{1}{2}\biggl[ A_s (1-e^2) \biggr]
-+ \biggl[ A_s - A_{\ell s}a_\ell^2 \biggl( \frac{\varpi^2 }{a_\ell^2}\biggr)\biggr]\zeta
+-  \frac{1}{6}\biggl[ A_{ss} a_\ell^2(1-e^2)^2  \biggr] \, .
-+
+</math>&nbsp; &nbsp; &nbsp; [0.2045061]
-A_\ell \biggl(\frac{\varpi^2}{a_\ell^2}\biggr)
+  </td>
-- \frac{1}{2} A_{\ell \ell} a_\ell^2  \biggl(\frac{\varpi^4}{a_\ell^4}\biggr)
+</tr>
-\, .
+</table>
-</math>
+</td></tr></table>
+<table border="0" align="center" cellpadding="8" width="80%">
+<tr>
+  <td align="left">
+For an oblate-spheroidal configuration having eccentricity, <math>e=0.6 ~\Rightarrow~ a_s/a_\ell = 0.8</math>, the figure displayed here, on the right, shows how the normalized gas pressure <math>(P^*_\mathrm{deduced}/P^*_c)</math> varies with height above the mid-plane <math>(\zeta)</math> at three different distances from the symmetry axis:  (blue) <math>\chi = 0.0</math>, (orange) <math>\chi = 0.6</math>, and (gray) <math>\chi = 0.75</math>.
+<table border="1" align="center" cellpadding="5">
+<tr>
+  <td align="center" rowspan="2">circular<br />marker<br />color</td>
+  <td align="center" rowspan="2">chosen<br /><math>\chi</math></td>
+  <td align="center" colspan="2">resulting &hellip;</td>
+</tr>
+<tr>
+  <td align="center">surface <math>\zeta</math></td>
+  <td align="center">mid-plane<br />pressure</td>
+</tr>
+<tr>
+  <td align="center"><font color="blue">blue</font></td>
+  <td align="center"><math>0.00</math></td>
+  <td align="center"><math>0.8000</math></td>
+  <td align="center"><math>1.00000</math></td>
+</tr>
+<tr>
+  <td align="center"><font color="orange">orange</font></td>
+  <td align="center"><math>0.60</math></td>
+  <td align="center"><math>0.6400</math></td>
+  <td align="center"><math>0.32667</math></td>
+</tr>
+<tr>
+  <td align="center"><font color="gray">gray</font></td>
+  <td align="center"><math>0.75</math></td>
+  <td align="center"><math>0.52915</math></td>
+  <td align="center"><math>0.13085</math></td>
+</tr>
+</table>
+  </td>
+  <td align="center">
+[[File:FerrersVerticalPressureD.png|center|500px|Ferrers Vertical Pressure ]]
    </td>
 </tr>
 </table>
-<table border="1" align="center" cellpadding="8" width="80%"><tr><td align="left">
+Inserting the expression for <math>C_\lambda</math> into our derived expression for <math>P^*_\mathrm{deduced}</math> gives,
-Given values of the three parameters, <math>e</math>, <math>\varpi</math>, and <math>\phi_\mathrm{choice}</math>, this last expression can be viewed as a quadratic equation for <math>\zeta</math>.  Specifically,
 <table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>P^*_\mathrm{deduced} </math></td>
-<math>0</math>
-  </td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\alpha \zeta^2 + \beta\zeta + \gamma \, ,
+(\mathrm{coef1}) \cdot \biggl[ \zeta^2 - (1-e^2)( 1 - \chi^2) \biggr]
++  (\mathrm{coef2} )\cdot \biggl[ \zeta^4 - (1-e^2)^2( 1 - \chi^2)^2 \biggr]
++  ( \mathrm{coef3}) \cdot \biggl[ \zeta^6 - (1-e^2)^3( 1 - \chi^2)^3\biggr]
+\, .
 </math>
    </td>
 </tr>
 </table>
-where,
+----
+Note for later use that,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math> \frac{\partial C_\chi}{\partial\chi}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+&hellip;
+  </td>
+</tr>
+</table>
+====Isobaric Surfaces====
+By design, the mass within our oblate-spheroidal configuration is distributed in such a way that iso-density surfaces are concentric spheroids.  As stated earlier, the relevant mathematically prescribed density distribution is,
 <table border="0" cellpadding="5" align="center">
@@ Line 495: / Line 630: @@
 <tr>
    <td align="right">
-<math>\alpha</math>
+<math>\frac{\rho(\chi, \zeta)}{\rho_c}</math>
+  </td>
+  <td align="center">
+<math>=</math>
    </td>
-  <td align="center"><math>\equiv</math></td>
    <td align="left">
 <math>
-\frac{1}{2}  A_{ss} a_\ell^2
+\biggl[1 - \chi^2 - \zeta^2(1-e^2)^{-1} \biggr]
-</math>
+\, .</math>
    </td>
 </tr>
+</table>
+In order to determine the relative stability of each configuration, it will be important to ascertain whether or not isobaric surfaces are also concentric spheroids.  (If they are, then we can say that each configuration obeys a [[SR#Barotropic_Structure|barotropic]] &#8212; but not necessarily a polytropic &#8212; equation of state; see, for example, the [[AxisymmetricConfigurations/SolutionStrategies#Simple_Rotation_Profile_and_Centrifugal_Potential|accompanying relevant excerpt]] drawn from p. 466 of {{ Lebovitz67_XXXIV }}.)  In an effort to make this determination for our <math>e = 0.6</math> spheroid, we first examine the iso-density surface for which <math>\rho/\rho_c = 0.3</math>.  Via the expression,
+<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-&nbsp;
+<math>\zeta^2</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+(1-e^2)\biggl[1 - \chi^2 - \frac{\rho}{\rho_c} \biggr]
+=
+.64 \biggl[1 - \chi^2 - 0.3 \biggr]
+\, ,</math>
    </td>
+</tr>
+</table>
+we can immediately determine that our three chosen radial cuts <math>(\chi = 0.0, 0.6, 0.75)</math> intersect this iso-density surface at the vertical locations, respectively, <math>\zeta = 0.66933, 0.46648, 0.29665</math>; these numerical values have been recorded in the following table.  The table also contains coordinates for the points where our three cuts intersect the <math>(e = 0.6)</math> iso-density surface for which <math>\rho/\rho_c = 0.6</math>.
+<table border="1" align="center" cellpadding="5">
+<tr>
+  <td align="center" rowspan="2">diamond<br />marker<br />color</td>
+  <td align="center" rowspan="2">chosen<br /><math>\rho/\rho_c</math></td>
+  <td align="center" rowspan="2">chosen<br /><math>\chi</math></td>
+  <td align="center" colspan="2">resulting &hellip;</td>
+</tr>
+<tr>
+  <td align="center">&nbsp; &nbsp; <math>\zeta</math> &nbsp; &nbsp;</td>
+  <td align="center">normalized<br />pressure</td>
+</tr>
+<tr>
+  <td align="center" rowspan="3"><font color="darkgreen">green</font></td>
+  <td align="center" rowspan="3"><math>0.3</math></td>
+  <td align="center" rowspan="1"><math>0.00</math></td>
+  <td align="center" rowspan="1"><math>0.66933</math></td>
+  <td align="center" rowspan="1"><math>0.060466</math></td>
+</tr>
+<tr>
+  <td align="center" rowspan="1"><math>0.60</math></td>
+  <td align="center" rowspan="1"><math>0.46648</math></td>
+  <td align="center" rowspan="1"><math>0.057433</math></td>
+</tr>
+<tr>
+  <td align="center" rowspan="1"><math>0.75</math></td>
+  <td align="center" rowspan="1"><math>0.29665</math></td>
+  <td align="center" rowspan="1"><math>0.055727</math></td>
+</tr>
+<tr>
+  <td align="center" rowspan="3"><font color="purple">purple</font></td>
+  <td align="center" rowspan="3"><math>0.6</math></td>
+  <td align="center" rowspan="1"><math>0.00</math></td>
+  <td align="center" rowspan="1"><math>0.50596</math></td>
+  <td align="center" rowspan="1"><math>0.292493</math></td>
+</tr>
+<tr>
+  <td align="center" rowspan="1"><math>0.60</math></td>
+  <td align="center" rowspan="1"><math>0.16000</math></td>
+  <td align="center" rowspan="1"><math>0.280361</math></td>
+</tr>
+<tr>
+  <td align="center" rowspan="1"><math>0.75</math></td>
+  <td align="center" rowspan="1">n/a</td>
+  <td align="center" rowspan="1">n/a</td>
+</tr>
+</table>
+For each of these five <math>(\chi,\zeta)</math> coordinate pairs, we have used our above derived expression for <math>P^*_\mathrm{deduced}/P^*_c</math> to calculate the "normalized pressure" at the relevant point inside the configuration.  These results appear in the last column of the table; they also have been marked in the accompanying figure: dark green diamonds mark the points relevant to our choice of <math>\rho/\rho_c = 0.3</math> and purple diamonds mark the points relevant to our choice of <math>\rho/\rho_c = 0.6</math>. Notice that the normalized density is everywhere lower than <math>0.6</math> along the <math>\chi = 0.75</math> cut, so the final row in the table has been marked "n/a" (not applicable).
+The dark green diamond-shaped markers in the figure  &#8212; along with the associated tabular data &#8212; show that at three separate points along the <math>\rho/\rho_c = 0.3</math> iso-density surface, the normalized pressure is ''nearly'' &#8212; but not exactly &#8212; the same; its value is approximately <math>0.057</math>.  Similarly, the purple diamond-shaped markers show that at two separate points along the <math>\rho/\rho_c = 0.6</math> iso-density surface, the normalized pressure is nearly the same; in this case its value is approximately <math>0.28</math>.  This seems to indicate that, throughout our configuration, the isobaric surfaces are almost &#8212; but not exactly &#8212; aligned with iso-density surfaces.
+====Now Play With Radial Pressure Gradient====
+After multiplying through by <math>\rho/\rho_c</math>, the last term on the RHS of the <math>\hat{e}_\varpi</math> component is given by the expression,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math>\frac{\rho}{\rho_c} \cdot   \biggl[\frac{1}{(-\pi G\rho_c a_\ell^2)} \biggr] \frac{\partial \Phi_\mathrm{grav}}{\partial \chi}</math></td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{3}\biggl\{
+\biggl[1 - \chi^2 - \zeta^2(1-e^2)^{-1} \biggr]  \biggl[
-\frac{( 4e^2 - 3 )}{e^4(1-e^2)}
+(A_{\ell s} a_\ell^2 \zeta^2 - A_\ell )\chi
-+
++ A_{\ell\ell} a_\ell^2 \chi^3
-\frac{3 (1-e^2)^{1 / 2}}{e^4} \biggl[\frac{\sin^{-1}e}{e}\biggr]
+\biggr]
-\biggr\}
-\, ,
 </math>
    </td>
@@ Line 523: / Line 734: @@
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-<math>\beta</math>
+   <td align="center"><math>=</math></td>
-  </td>
-   <td align="center"><math>\equiv</math></td>
    <td align="left">
 <math>
-A_{\ell s}a_\ell^2 \biggl( \frac{\varpi^2 }{a_\ell^2}\biggr) - A_s
+\biggl[ (A_{\ell s} a_\ell^2 \zeta^2 - A_\ell )\chi + A_{\ell\ell} a_\ell^2 \chi^3\biggr]
+- 2\chi^2
+\biggl[ (A_{\ell s} a_\ell^2 \zeta^2 - A_\ell )\chi + A_{\ell\ell} a_\ell^2 \chi^3\biggr]
+- 2\zeta^2(1-e^2)^{-1}
+\biggl[(A_{\ell s} a_\ell^2 \zeta^2 - A_\ell )\chi + A_{\ell\ell} a_\ell^2 \chi^3\biggr]
 </math>
    </td>
@@ Line 535: / Line 748: @@
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-&nbsp;
-  </td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{e^4}\biggl\{(3-e^2) -  3(1-e^2)^{1 / 2} \frac{\sin^{-1}e}{e}  \biggr\}
+(A_{\ell s} a_\ell^2 \zeta^2 - A_\ell )\chi
-\biggl( \frac{\varpi^2 }{a_\ell^2}\biggr)
++ 2\biggl[ A_{\ell\ell} a_\ell^2
--
++
-\frac{2}{e^2} \biggl[  (1-e^2)^{-1/2} - \frac{\sin^{-1}e}{e} \biggr] (1-e^2)^{1 / 2}
+(A_\ell - A_{\ell s} a_\ell^2 \zeta^2 ) \biggr]\chi^3
-\, ,
+- 2A_{\ell\ell} a_\ell^2 \chi^5
++ 2(1-e^2)^{-1}
+\biggl[(A_\ell\zeta^2 - A_{\ell s} a_\ell^2 \zeta^4 )\chi - A_{\ell\ell} a_\ell^2 \zeta^2\chi^3\biggr]
 </math>
    </td>
@@ Line 551: / Line 764: @@
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-<math>\gamma</math>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl[ (A_{\ell s} a_\ell^2 \zeta^2 - A_\ell ) + (1-e^2)^{-1}(A_\ell\zeta^2 - A_{\ell s} a_\ell^2 \zeta^4 )\biggr]\chi
++ 2\biggl[ A_{\ell\ell} a_\ell^2 + (A_\ell - A_{\ell s} a_\ell^2 \zeta^2 ) - (1-e^2)^{-1}A_{\ell\ell} a_\ell^2 \zeta^2\biggr]\chi^3
+- 2A_{\ell\ell} a_\ell^2 \chi^5
+\, .
+ </math>
    </td>
-   <td align="center"><math>\equiv</math></td>
+</tr>
+</table>
+If we replace the normalized pressure by <math>P^*_\mathrm{deduced}</math>, the first term on the RHS of the <math>\hat{e}_\varpi</math> component becomes,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math>\frac{\partial P^*_\mathrm{deduced}}{\partial\chi} </math></td>
+   <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\phi_\mathrm{choice}
+\frac{\partial}{\partial \chi}\biggl\{
-+
+\biggl[-A_s \zeta^2 + \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 + \frac{1}{2}(1-e^2)^{-1}A_s\zeta^4 - \frac{1}{3}(1-e^2)^{-1}A_{ss} a_\ell^2  \zeta^6 \biggr]\chi^0
-\frac{1}{2} A_{\ell \ell} a_\ell^2  \biggl(\frac{\varpi^4}{a_\ell^4}\biggr)
++ \biggl[ A_{\ell s}a_\ell^2 \zeta^2 + A_s\zeta^2
--
+- \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 - \frac{1}{2}(1-e^2)^{-1}(A_{\ell s}a_\ell^2 \zeta^4 )
-A_\ell \biggl(\frac{\varpi^2}{a_\ell^2}\biggr)
+\biggr]\chi^2
++  \biggl[- A_{\ell s}a_\ell^2 \zeta^2 \biggr]\chi^4 + P_c^*
+\biggr\}
 </math>
    </td>
@@ Line 567: / Line 797: @@
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-&nbsp;
-  </td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\phi_\mathrm{choice}
+\biggl[ A_{\ell s}a_\ell^2 \zeta^2 + A_s\zeta^2
-+
+- \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 - \frac{1}{2}(1-e^2)^{-1}(A_{\ell s}a_\ell^2 \zeta^4 )
-\frac{1}{8e^4}\biggl\{- (3 + 2e^2) (1-e^2)+3 (1 - e^2)^{1 / 2} \biggl[\frac{\sin^{-1}e}{e}\biggr] \biggr\}\biggl(\frac{\varpi^4}{a_\ell^4}\biggr)
+\biggr]\chi
--
++  4\biggl[- A_{\ell s}a_\ell^2 \zeta^2 \biggr]\chi^3
-\frac{1}{e^2} \biggl[  \frac{\sin^{-1}e}{e} - (1-e^2)^{1/2} \biggr] (1-e^2)^{1 / 2} \biggl(\frac{\varpi^2}{a_\ell^2}\biggr)
-\, .
 </math>
    </td>
 </tr>
 </table>
-The solution of this quadratic equation gives,
+Hence,
 <table border="0" cellpadding="5" align="center">
@@ Line 589: / Line 816: @@
 <tr>
    <td align="right">
-<math>\zeta</math>
+<math>
+\frac{1}{\chi^3} \cdot \frac{j^2}{(\pi G\rho_c a_\ell^4)} \cdot \frac{\rho}{\rho_c}
+</math>
+  </td>
+  <td align="center">
+=
    </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{2\alpha}\biggl\{ - \beta \pm \biggl[\beta^2 - 4\alpha\gamma \biggr]^{1 / 2}\biggr\}
+\biggl[ \frac{\partial P_\mathrm{deduced}^*}{\partial \chi} \biggr]
-\, .
+- \frac{\rho}{\rho_c} \cdot \frac{\partial }{\partial \chi}\biggl[ \frac{\Phi_\mathrm{grav}}{(-~\pi G\rho_c a_\ell^2)} \biggr]
 </math>
    </td>
 </tr>
 </table>
-Given that in this physical system, <math>\zeta = z^2/a_\ell^2</math> must be positive, we must choose the superior root.  We conclude therefore that,
+===10<sup>th</sup> Try===
+====Repeating Key Relations====
 <table border="0" cellpadding="5" align="center">
 <tr>
+  <td align="left"><font color="orange"><b>Density:</b></font></td>
    <td align="right">
-<math>\frac{z^2}{a_\ell^2}</math>
+<math>\frac{\rho(\varpi, z)}{\rho_c}</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+\biggl[1 - \chi^2 - \zeta^2(1-e^2)^{-1} \biggr]
+\, ,</math>
+  </td>
+</tr>
+<tr>
+  <td align="left"><font color="orange"><b>Gravitational Potential:</b></font></td>
+  <td align="right">
+<math>\frac{ \Phi_\mathrm{grav}(\varpi,z)}{(-\pi G\rho_c a_\ell^2)} </math>
+  </td>
+  <td align="center">
+<math>=</math>
    </td>
-  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\frac{1}{2\alpha}\biggl\{ \biggl[\beta^2 - 4\alpha\gamma \biggr]^{1 / 2} - \beta \biggr\}
+\frac{1}{2} I_\mathrm{BT}
+- A_\ell \chi^2  - A_s \zeta^2
+ + \frac{1}{2}\biggl[(A_{s s} a_\ell^2) \zeta^4
++ 2(A_{\ell s}a_\ell^2 )\chi^2 \zeta^2
++ (A_{\ell \ell} a_\ell^2)  \chi^4 \biggr]
 \, .
 </math>
    </td>
 </tr>
-</table>
+</tr>
-<font color="red">But check this statement because it appears that <math>\beta</math> will sometimes be negative.</font>
-</td></tr></table>
-Here we present a quantitatively accurate depiction of the shape of the (Ferrers) gravitational potential that arises from oblate-spheroidal configurations having a parabolic density distribution.  We closely follow the discussion of [[Apps/MaclaurinSpheroids#Example_Equi-gravitational-potential_Contours|equi-gravitational potential contours that arise in (uniform-density) Maclaurin spheroids]].  In order to facilitate comparison with Maclaurin spheroids, we will focus on a model with &hellip;
-<table border="0" align="center" width="80%">
 <tr>
-   <td align="center"><math>\frac{a_s}{a_\ell} = 0.582724 \, ,</math></td>
+   <td align="left"><font color="orange"><b>Vertical Pressure Gradient:</b></font></td>
-   <td align="center"><math>e = 0.81267 \, ,</math></td>
+  <td align="right"><math>\biggl[\frac{1}{(\pi G\rho_c^2 a_\ell^2)} \biggr] \frac{\partial P}{\partial \zeta}</math></td>
-   <td align="center">&nbsp;</td>
+   <td align="center"><math>=</math></td>
+   <td align="left">
+<math>
+\frac{\rho}{\rho_c} \cdot  \biggl[
+A_{\ell s}a_\ell^2 \chi^2\zeta - 2A_s \zeta
++  2A_{ss} a_\ell^2  \zeta^3
+\biggr]
+</math>
+  </td>
 </tr>
+</table>
+From the [[#Starting_Key_Relations|above (9<sup>th</sup> Try) examination]] of the vertical pressure gradient, we determined that a reasonably good approximation for the normalized pressure throughout the configuration is given by the expression,
+<table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="center"><math>A_\ell = A_m = 0.51589042 \, ,</math></td>
+   <td align="right"><math>\biggl[\frac{1}{(\pi G\rho_c^2 a_\ell^2)} \biggr] \int \biggl[\frac{\partial P}{\partial \zeta}\biggr] d\zeta </math></td>
-   <td align="center"><math>A_s = 0.96821916 \, ,</math></td>
+   <td align="center"><math>=</math></td>
-   <td align="center"><math>I_\mathrm{BT} = 1.360556 \, ,</math></td>
+   <td align="left">
+<math>
+\biggl[-A_s \zeta^2 + \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 + \frac{1}{2}(1-e^2)^{-1}A_s\zeta^4 - \frac{1}{3}(1-e^2)^{-1}A_{ss} a_\ell^2  \zeta^6 \biggr]\chi^0
++ \biggl[ A_{\ell s}a_\ell^2 \zeta^2 + A_s\zeta^2
+- \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 - \frac{1}{2}(1-e^2)^{-1}(A_{\ell s}a_\ell^2 \zeta^4 )
+\biggr]\chi^2
++  \biggl[- A_{\ell s}a_\ell^2 \zeta^2 \biggr]\chi^4 + ~\mathrm{const.}
+</math>
+  </td>
 </tr>
+</table>
+If we set <math>\chi = 0</math> &#8212; that is, if we look along the vertical axis &#8212; this approximation should be particularly good, resulting in the expression,
+<table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="center"><math>a_\ell^2 A_{\ell \ell} = 0.3287756 \, ,</math></td>
+   <td align="right"><math>P_z \equiv \biggl\{ \biggl[\frac{1}{(\pi G\rho_c^2 a_\ell^2)} \biggr] \int \biggl[\frac{\partial P}{\partial \zeta}\biggr] d\zeta \biggr\}_{\chi=0}</math></td>
-   <td align="center"><math>a_\ell^2 A_{s s} = 1.5066848 \, ,</math></td>
+   <td align="center"><math>=</math></td>
-   <td align="center"><math>a_\ell^2 A_{\ell s} = 0.6848975 \, .</math></td>
+   <td align="left">
+<math>P_c^* - A_s \zeta^2 + \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 + \frac{1}{2}(1-e^2)^{-1}A_s\zeta^4 - \frac{1}{3}(1-e^2)^{-1}A_{ss} a_\ell^2  \zeta^6 \, .
+</math>
+  </td>
 </tr>
 </table>
-[<font color="red">NOTE:</font> &nbsp; Along the Maclaurin spheroid sequence, this is the eccentricity that marks bifurcation to the Jacobi ellipsoid sequence &#8212; see the first model listed in Table IV (p. 103) of [<b>[[Appendix/References#EFE|<font color="red">EFE</font>]]</b>] and/or see Tables 1 and 2 of [[ThreeDimensionalConfigurations/JacobiEllipsoids|our discussion of the Jacobi ellipsoid sequence]].  It is unlikely that this same eccentricity has a comparably special physical relevance along the sequence of spheroids having parabolic density distributions.]
+<table border="1" align="center" cellpadding="8" width="80%"><tr><td align="left">
+Note that in the limit that <math>z \rightarrow a_s</math> &#8212; that is, at the pole along the vertical (symmetry) axis where the <math>P_z</math> should drop to zero &#8212; we should set <math>\zeta \rightarrow (1 - e^2)^{1 / 2}</math>.  This allows us to determine the central pressure.
-The largest value of the gravitational potential that will arise inside (and on the surface) of the configuration at <math>(\varpi, z) = (1, 0)</math>.  That is, when,
 <table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>P_c^* </math></td>
-<math>\alpha</math>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>A_s (1-e^2) - \frac{1}{2}A_{ss}a_\ell^2 (1-e^2)^2 - \frac{1}{2}(1-e^2)^{-1}A_s(1-e^2)^2 + \frac{1}{3}(1-e^2)^{-1}A_{ss} a_\ell^2  (1-e^2)^3
+</math>
    </td>
-   <td align="center"><math>\equiv</math></td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+   <td align="center"><math>=</math></td>
    <td align="left">
-<math>
+<math>A_s (1-e^2)  - \frac{1}{2}A_s(1-e^2) + \frac{1}{3}A_{ss} a_\ell^2  (1-e^2)^2 - \frac{1}{2}A_{ss}a_\ell^2 (1-e^2)^2
-\frac{1}{2}  A_{ss} a_\ell^2
 </math>
    </td>
@@ Line 658: / Line 945: @@
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-<math>\beta</math>
+   <td align="center"><math>=</math></td>
-  </td>
-   <td align="center"><math>\equiv</math></td>
    <td align="left">
-<math>
+<math>\frac{1}{2}A_s(1-e^2) - \frac{1}{6}A_{ss} a_\ell^2  (1-e^2)^2 \, .
-A_{\ell s}a_\ell^2  - A_s
 </math>
    </td>
 </tr>
+</table>
+</td></tr></table>
+This means that, along the vertical axis, the pressure gradient is,
+<table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>P_z \equiv \biggl\{ \biggl[\frac{1}{(\pi G\rho_c^2 a_\ell^2)} \biggr] \int \biggl[\frac{\partial P}{\partial \zeta}\biggr] d\zeta \biggr\}_{\chi=0}</math></td>
-<math>\gamma</math>
+   <td align="center"><math>=</math></td>
-  </td>
-   <td align="center"><math>\equiv</math></td>
    <td align="left">
-<math>
+<math>P_c^* - A_s \zeta^2 + \frac{1}{2}A_{ss}a_\ell^2 \zeta^4 + \frac{1}{2}(1-e^2)^{-1}A_s\zeta^4 - \frac{1}{3}(1-e^2)^{-1}A_{ss} a_\ell^2  \zeta^6 \, .
-\phi_\mathrm{choice}
-+
-\frac{1}{2} A_{\ell \ell} a_\ell^2
--
-A_\ell
 </math>
    </td>
@@ Line 686: / Line 970: @@
 </table>
+<table border="0" cellpadding="5" align="center">
-----
+<tr>
+  <td align="right"><math>\frac{\partial P_z}{\partial\zeta}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>- 2A_s \zeta + 2A_{ss}a_\ell^2 \zeta^3 + 2(1-e^2)^{-1}A_s\zeta^3 - 2(1-e^2)^{-1}A_{ss} a_\ell^2  \zeta^5 \, .
+</math>
+  </td>
+</tr>
+</table>
+This should match the more general "<font color="orange">vertical pressure gradient</font>" expression when we set, <math>\chi=0</math>, that is,
 <table border="0" cellpadding="5" align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>\biggl\{ \biggl[\frac{1}{(\pi G\rho_c^2 a_\ell^2)} \biggr] \frac{\partial P}{\partial \zeta} \biggr\}_{\chi=0}</math></td>
-<math>\phi_\mathrm{choice}\biggr|_\mathrm{max} </math>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl[ 1 - \cancelto{0}{\chi^2} - \zeta^2(1-e^2)^{-1}\biggr]\cdot \biggl[
+A_{\ell s}a_\ell^2 \zeta \cancelto{0}{\chi^2} - 2A_s \zeta
++  2A_{ss} a_\ell^2  \zeta^3
+\biggr]
+</math>
    </td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-A_\ell
+\biggl[- 2A_s \zeta  +  2A_{ss} a_\ell^2  \zeta^3   \biggr]
-- \frac{1}{2} A_{\ell \ell} a_\ell^2 = 0.3515026 \,  .
++ \zeta^2(1-e^2)^{-1} \biggl[2A_s \zeta  -  2A_{ss} a_\ell^2  \zeta^3   \biggr]
 </math>
    </td>
 </tr>
 </table>
+<b><font color="red">Yes! The expressions match!</font></b>
 =See Also=
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ParabolicDensity/Axisymmetric/Structure: Difference between revisions

Latest revision as of 15:36, 16 November 2024

Parabolic Density Distribution[edit]

Axisymmetric (Oblate) Equilibrium Structures[edit]

Tentative Summary[edit]

Known Relations[edit]

Play With Vertical Pressure Gradient[edit]

Isobaric Surfaces[edit]

Now Play With Radial Pressure Gradient[edit]

10th Try[edit]

Repeating Key Relations[edit]

See Also[edit]

Navigation menu

Search

10^th Try[edit]