BiPolytrope with n_c = 1 and n_e = 5

Murphy (1983) Analytic (n_c, n_e) = (1, 5)

Comment by J. E. Tohline on 12 April 2015: I became aware of the published discussions of this system by Murphy (1983) and Murphy & Fiedler (1985b) in March of 2015 after searching the internet for previous analyses of radial oscillations in polytropes and, then, reading through Horedt's (2004) §2.8.1 discussion of composite polytropes.

Here we construct a system of bipolytropic configurations in which the core has an

n_{c} = 1

polytropic index and the envelope has an

n_{e} = 5

polytropic index. As in the case of our separately discussed, "mirror image" bipolytropic configurations having

(n_{c}, n_{e}) = (5, 1)

, this system is particularly interesting because the entire structure can be described by closed-form, analytic expressions. Bipolytropes of this type were first constructed by J. O. Murphy (1983, Proc. Astr. Soc. of Australia, 5, 175), and attributes of their physical structure were further discussed by J. O. Murphy & R. Fiedler (1985a, Proc. Astr. Soc. of Australia, 6, 219); additional, closely related references are given below. In the discussion that follows, we will be heavily referencing Murphy's (1983) work.

Part I: Steps 2 thru 7

Part II: Analytic Solution of Interface Relation

III: Modeling

Steps 2 & 3

Based on the discussion presented elsewhere of the structure of an isolated $n = 1$ polytrope, the core of this bipolytrope will have the following properties:

$θ (ξ) = \frac{\sin ξ}{ξ} \Rightarrow θ_{i} = \frac{\sin ξ_{i}}{ξ_{i}};$

$\frac{d θ}{d ξ} = [\frac{\cos ξ}{ξ} - \frac{\sin ξ}{ξ^{2}}] \Rightarrow (\frac{d θ}{d ξ})_{i} = [\frac{\cos ξ_{i}}{ξ_{i}} - \frac{\sin ξ_{i}}{ξ_{i}^{2}}] .$

The first zero of the function $θ (ξ)$ and, hence, the surface of the corresponding isolated $n = 1$ polytrope is located at $ξ_{s} = π$ . Hence, the interface between the core and the envelope can be positioned anywhere within the range, $0 < ξ_{i} < π$ .

Step 4: Throughout the core ( $0 \leq ξ \leq ξ_{i}$ )

Specify: $K_{c}$ and $ρ_{0} \Rightarrow$
$ρ$	$=$	$ρ_{0} θ^{n_{c}}$	$=$	$ρ_{0} (\frac{\sin ξ}{ξ})$
$P$	$=$	$K_{c} ρ_{0}^{1 + 1 / n_{c}} θ^{n_{c} + 1}$	$=$	$K_{c} ρ_{0}^{2} (\frac{\sin ξ}{ξ})^{2}$
$r$	$=$	$[\frac{(n_{c} + 1) K_{c}}{4 π G}]^{1 / 2} ρ_{0}^{(1 - n_{c}) / (2 n_{c})} ξ$	$=$	$[\frac{K_{c}}{2 π G}]^{1 / 2} ξ$
$M_{r}$	$=$	$4 π [\frac{(n_{c} + 1) K_{c}}{4 π G}]^{3 / 2} ρ_{0}^{(3 - n_{c}) / (2 n_{c})} (- ξ^{2} \frac{d θ}{d ξ})$	$=$	$4 π [\frac{K_{c}}{2 π G}]^{3 / 2} ρ_{0} [\sin ξ - ξ \cos ξ]$

Step 5: Interface Conditions

			Setting $n_{c} = 1$ and $n_{e} = 5 \Rightarrow$
$\frac{ρ_{e}}{ρ_{0}}$	$=$	$(\frac{μ_{e}}{μ_{c}}) θ_{i}^{n_{c}} ϕ_{i}^{- n_{e}}$	$=$	$(\frac{μ_{e}}{μ_{c}}) θ_{i} ϕ_{i}^{- 5}$
$(\frac{K_{e}}{K_{c}})$	$=$	$ρ_{0}^{1 / n_{c} - 1 / n_{e}} (\frac{μ_{e}}{μ_{c}})^{- (1 + 1 / n_{e})} θ_{i}^{1 - n_{c} / n_{e}}$	$=$	$[ρ_{0}^{4} (\frac{μ_{e}}{μ_{c}})^{- 6} θ_{i}^{4}]^{1 / 5}$
$\frac{η_{i}}{ξ_{i}}$	$=$	$[\frac{n_{c} + 1}{n_{e} + 1}]^{1 / 2} (\frac{μ_{e}}{μ_{c}}) θ_{i}^{(n_{c} - 1) / 2} ϕ_{i}^{(1 - n_{e}) / 2}$	$=$	$(\frac{1}{3})^{1 / 2} (\frac{μ_{e}}{μ_{c}}) ϕ_{i}^{- 2}$
$(\frac{d ϕ}{d η})_{i}$	$=$	$[\frac{n_{c} + 1}{n_{e} + 1}]^{1 / 2} θ_{i}^{- (n_{c} + 1) / 2} ϕ_{i}^{(n_{e} + 1) / 2} (\frac{d θ}{d ξ})_{i}$	$=$	$(\frac{1}{3})^{1 / 2} θ_{i}^{- 1} (\frac{d θ}{d ξ})_{i} ϕ_{i}^{3}$

Alternative: In our introductory description of how to build a bipolytropic structure, we pointed out that, instead of employing these last two fitting conditions, Chandrasekhar [C67] found it useful to employ, instead, the ratio of the $3^{r d}$ to $4^{t h}$ expressions, which in the present case produces,

$\frac{η_{i} ϕ_{i}^{5}}{(d ϕ / d η)_{i}} = \frac{ξ_{i} θ_{i}}{(d θ / d ξ)_{i}} (\frac{μ_{e}}{μ_{c}}),$

and the product of the $3^{r d}$ and $4^{t h}$ expressions, which in the present case generates,

$\frac{3 η_{i} (d ϕ / d η)_{i}}{ϕ_{i}} = \frac{ξ_{i} (d θ / d ξ)_{i}}{θ_{i}} (\frac{μ_{e}}{μ_{c}}) .$

In what follows we will sometimes refer to the first of these two expressions as Chandrasekhar's "U-constraint" and we will sometimes refer to the second as Chandrasekhar's "V-constraint." As is explained in an accompanying discussion, Murphy (1983) followed Chandrasekhar's lead and extracted fitting conditions from this last pair of expressions. In seeking the most compact analytic solution, we have found it advantageous to invoke our standard $3^{r d}$ fitting expression in tandem with the Chandrasekhar's V-constraint.

Step 6: Envelope Solution

Comment by J. E. Tohline on 20 April 2015: There is a type-setting error in this function expression as published in the upper left-hand column of the second page of the article by Murphy (1983); the sine function in the denominator should be sine-squared, as presented here.

Following the work of Murphy (1983) and of Murphy & Fiedler (1985a), we will adopt for the envelope's structure the F-Type solution of the

n = 5

Lane-Emden function discovered by S. Srivastava (1968, ApJ, 136, 680) and described in an accompanying discussion, namely,

$ϕ$	$=$	$\frac{B_{0}^{- 1} \sin [\ln (A_{0} η)^{1 / 2})]}{η^{1 / 2} {3 - 2 \sin^{2} [\ln (A_{0} η)^{1 / 2}]}^{1 / 2}}$
	$=$	$\frac{B_{0}^{- 1} \sin Δ}{η^{1 / 2} (3 - 2 \sin^{2} Δ)^{1 / 2}},$

Note that our homology factor and scaling coefficient serve virtually the same roles as the homology factor, A, and scaling coefficient, B, used by Murphy (1983), but they are not mathematically identical so we have added a subscript "0" to highlight the distinctions.

where

A_{0}

is a "homology factor" and

B_{0}

is an overall scaling coefficient — the values of both will be determined presently from the interface conditions — and we have introduced the notation,

$Δ \equiv \ln (A_{0} η)^{1 / 2} = \frac{1}{2} (\ln A_{0} + \ln η) .$

The first derivative of Srivastava's function is,

$\frac{d ϕ}{d η}$

$=$

$\frac{B_{0}^{- 1} [3 \cos Δ - 3 \sin Δ + 2 \sin^{3} Δ]}{2 η^{3 / 2} (3 - 2 \sin^{2} Δ)^{3 / 2}} .$

As has been explained in the context of our more general discussion of Srivastava's function, if we ignore, for the moment, the additional " $m π$ " phase shift that can be attached to a determination of the angle, $Δ$ , the physically viable interval for the dimensionless radial coordinate is, $e^{2 π} \geq A_{0} η \geq η_{c r i t} \equiv e^{2 \tan^{- 1} (1 + 2^{1 / 3})} .$

For this bipolytropic configuration, it is worth emphasizing how the dimensionless radial coordinate of the $n_{e} = 5$ envelope, $η$ , is related to the dimensionless radial coordinate of the $n_{c} = 1$ core, $ξ$ . Referring to the general setup procedure for constructing any bipolytropic configuration that has been presented in tabular form in a separate discussion, it is clear that in order for the radial coordinate, $r$ , to carry a consistent meaning throughout the model, we must have,

$r = [\frac{(n_{c} + 1) K_{c}}{4 π G}]^{1 / 2} ρ_{0}^{(1 - n_{c}) / (2 n_{c})} ξ$	$=$	$[\frac{(n_{e} + 1) K_{e}}{4 π G}]^{1 / 2} ρ_{e}^{(1 - n_{e}) / (2 n_{e})} η$
$\Rightarrow (\frac{K_{c}}{3 K_{e}}) ρ_{e}^{4 / 5}$	$=$	$(\frac{η}{ξ})^{2} .$

Referring back to the already established interface conditions, above, to relate $ρ_{e}$ to $ρ_{0}$ , and to re-express the ratio, $K_{e} / K_{c}$ , we therefore have,

$(\frac{η}{ξ})^{2}$	$=$	$\frac{1}{3} [ρ_{0}^{4} (\frac{μ_{e}}{μ_{c}})^{- 6} θ_{i}^{4}]^{- 1 / 5} [ρ_{0} (\frac{μ_{e}}{μ_{c}}) θ_{i} ϕ_{i}^{- 5}]^{4 / 5}$
$\Rightarrow \frac{η}{ξ}$	$=$	$(\frac{1}{3})^{1 / 2} (\frac{μ_{e}}{μ_{c}}) ϕ_{i}^{- 2} .$

While this result is not a surprise because the right-hand-side is the same expression that was presented, above, as the interface condition for the ratio, $η_{i} / ξ_{i}$ , it is nevertheless useful because it shows that the same relation works throughout the system — not just at the interface — and it clearly defines how we can swap back and forth between the two dimensionless radial coordinates when examining the structure and characteristics of this composite bipolytropic structure.

First Constraint

Calling upon Chandrasekhar's V-constraint, as just defined above — see also our accompanying discussion for elaboration on Murphy's (1983) "V_5F" and "V_1E" function notations — one fitting condition at the interface is,

$- \frac{2 ξ_{i}}{3 θ_{i}} (\frac{d θ}{d ξ})_{i} (\frac{μ_{e}}{μ_{c}})$	$=$	$2 [\frac{η (- d ϕ / d η)}{ϕ}]_{i}$
	$=$	$\frac{[3 \sin Δ_{i} - 2 \sin^{3} Δ_{i} - 3 \cos Δ_{i}]}{\sin Δ_{i} (3 - 2 \sin^{2} Δ_{i})}$
	$=$	$\frac{3 - 2 \sin^{2} Δ_{i} - 3 \cot Δ_{i}}{(3 - 2 \sin^{2} Δ_{i})} .$

The left-hand side of this expression is inherently positive over the physically viable radial coordinate range, $0 \geq ξ_{i} \geq π$ and its value is known once the radial coordinate of the edge of the core has been specified. So, defining the interface parameter,

$κ_{i} \equiv - \frac{2 θ_{i}^{'} ξ_{i}}{3 θ_{i}} (\frac{μ_{e}}{μ_{c}}),$

we will recast the first constraint into, what will henceforth be referred to as, the

Key Nonlinear Interface Relation

$κ_{i}$

$=$

$\frac{3 - 2 \sin^{2} Δ_{i} - 3 \cot Δ_{i}}{(3 - 2 \sin^{2} Δ_{i})} .$

In a separate subsection of this chapter, below, we present a closed-form analytic solution, $Δ_{i} (κ_{i})$ , to this nonlinear equation.

Second Constraint

Obtained from Third Interface Condition

Our 3^rd interface condition, as detailed above, states that,

$\frac{η_{i}}{ξ_{i}}$

$=$

$3^{- 1 / 2} (\frac{μ_{e}}{μ_{c}}) ϕ_{i}^{- 2} .$

If we now choose to normalize the interface amplitude such that, $ϕ_{i} = 1$ , then this condition establishes two relations: First, from the 3^rd interface condition alone,

$η_{i}$

$=$

$3^{- 1 / 2} (\frac{μ_{e}}{μ_{c}}) ξ_{i};$

and, second, from the definition of Srivastava's function, $ϕ$ , we deduce that the overall scaling parameter is,

$B_{0}^{2}$	$=$	$\frac{\sin^{2} Δ_{i}}{η_{i} (3 - 2 \sin^{2} Δ_{i})}$
	$=$	$\frac{\sqrt{3}}{ξ_{i}} (\frac{μ_{e}}{μ_{c}})^{- 1} (\frac{3}{\sin^{2} Δ_{i}} - 2)^{- 1} .$

Notice that, after the solution, $Δ_{i} (κ_{i})$ , of the key nonlinear interface relation has been determined, the first of these two relations also permits us to write,

$A_{0} η_{i}$	$=$	$e^{2 Δ_{i}}$
$\Rightarrow A_{0}$	$=$	$3^{1 / 2} (\frac{μ_{e}}{μ_{c}})^{- 1} ξ_{i}^{- 1} e^{2 Δ_{i}} .$

Throughout the envelope, therefore, the angle,

$Δ$

$=$

$\ln (A_{0} η)^{1 / 2} = \frac{1}{2} \ln [ξ \cdot ξ_{i}^{- 1} e^{2 Δ_{i}}] = Δ_{i} + \ln (\frac{ξ}{ξ_{i}})^{1 / 2} .$

Obtained from Chandrasekhar's U-constraint

We shall now demonstrate that the same expression for the scaling coefficient, $B_{0}$ , can alternatively be obtained from Chandrasekhar's U-constraint, without assuming that $ϕ_{i} = 1$ , after taking into account the result that already has been obtained from the V-constraint. As described above, the U-constraint is an alternative interface condition that may be written as,

$\frac{ξ_{i} θ_{i}}{(- d θ / d ξ)_{i}} (\frac{μ_{e}}{μ_{c}})$

$=$

$\frac{η_{i} ϕ_{i}^{5}}{(- d ϕ / d η)_{i}},$

which, in the particular case being examined here, becomes — again, see our accompanying discussion for elaboration on Murphy's (1983) "U_5F" and "U_1E" function notations —

$\frac{2 ξ_{i}^{2}}{3 κ_{i}} (\frac{μ_{e}}{μ_{c}})^{2}$	$=$	$(U_{5 F})_{i}$
	$=$	$\frac{2 B_{0}^{- 4} \sin^{4} Δ_{i}}{(3 - 2 \sin^{2} Δ_{i}) (3 - 2 \sin^{2} Δ_{i} - 3 \cot Δ_{i})} .$

Now, from our discussion, above, of the first constraint, we know that,

$(3 - 2 \sin^{2} Δ_{i} - 3 \cot Δ_{i})$

$=$

$(3 - 2 \sin^{2} Δ_{i}) κ_{i} .$

Hence, Chandrasekhar's U-constraint becomes,

$\frac{2 ξ_{i}^{2}}{3 κ_{i}} (\frac{μ_{e}}{μ_{c}})^{2}$	$=$	$\frac{2 B_{0}^{- 4} \sin^{4} Δ_{i}}{(3 - 2 \sin^{2} Δ_{i})^{2} κ_{i}}$
$\Rightarrow B_{0}^{4}$	$=$	$\frac{3 \sin^{4} Δ_{i}}{ξ_{i}^{2} (3 - 2 \sin^{2} Δ_{i})^{2}} (\frac{μ_{e}}{μ_{c}})^{- 2}$
$\Rightarrow B_{0}^{2}$	$=$	$\frac{\sqrt{3}}{ξ_{i}} (\frac{μ_{e}}{μ_{c}})^{- 1} (\frac{3}{\sin^{2} Δ_{i}} - 2)^{- 1},$

which, as predicted, is identical to what we learned from the third interface condition, alone.

Comment on Murphy's Scalings

Murphy's (1983) derivations also include an homology factor, $A$ , and an overall scaling factor, $B$ , but they are calculated differently from our $A_{0}$ and $B_{0}$ . In the righthand column of the third page of his paper, Murphy states that,

$A = \frac{ξ_{J}}{ζ_{J}},$

which, when translated into our notation $(ζ_{J} \to ξ_{i}$ and $ξ_{J} \to A_{0} η_{r o o t})$ gives,

$A = \frac{A_{0} η_{r o o t}}{ξ_{i}} .$

Now, in our derivation, $η_{r o o t}$ is synonymous with the location of the envelope interface, $η_{i}$ , as expressed in terms of the dimensionless radial coordinate associated with Srivastava's Lane-Emden function, so we can equally well state that,

$A = \frac{A_{0} η_{i}}{ξ_{i}} .$

Recalling that $ϕ_{i} = 1$ , we know from the interface conditions detailed above that,

$\frac{η_{i}}{ξ_{i}} = \frac{1}{3^{1 / 2}} (\frac{μ_{e}}{μ_{c}}) .$

Hence Murphy's homology factor, $A$ , is related to our homology factor, $A_{0}$ via the expression,

$A = \frac{A_{0}}{3^{1 / 2}} (\frac{μ_{e}}{μ_{c}}) .$

It is usually the value of this quantity, rather than simply our derived value of $A_{0}$ , that is tabulated below — both here and here — as we make quantitative comparisons between the characteristics of our derived models and those published by Murphy (1983) and by Murphy & Fiedler (1985a).

In the lefthand column of the fourth page of his paper, Murphy (1983) defines the coefficient $B$ in such a way that the value of the envelope function, $ϕ_{5 F}$ , equals the value of the core function, $θ_{1 E}$ , at the interface. Specifically, he sets,

$B$	$=$	$[\frac{ζ_{J}}{\sin ζ_{J}}] [\frac{A^{1 / 2} \sin (\ln \sqrt{A ζ_{J}})}{(A ζ_{J})^{1 / 2} {2 + \cos [\ln (A ζ_{J})]}^{1 / 2}}]$
	$=$	$[\frac{ζ_{J}}{\sin ζ_{J}}] [\frac{\sin (\ln \sqrt{A ζ_{J}})}{ζ_{J}^{1 / 2} {3 - 2 \sin^{2} (\ln \sqrt{A ζ_{J}})}^{1 / 2}}] .$

Switching to our terminology, that is, setting,

$\ln \sqrt{A ζ_{J}} \to Δ_{i}$ and, as before, $ζ_{J} \to ξ_{i},$

gives,

$B$	$=$	$[\frac{ξ_{i}}{\sin ξ_{i}}] [\frac{\sin Δ_{i}}{ξ_{i}^{1 / 2} (3 - 2 \sin^{2} Δ_{i})^{1 / 2}}]$
	$=$	$θ_{i}^{- 1} [ξ_{i}^{- 1} (\frac{3}{\sin^{2} Δ_{i}} - 2)^{- 1}]^{1 / 2} .$

Hence, in terms of the definition of our scaling coefficient, $B_{0}$ , derived above, we have,

$B$

$=$

$\frac{B_{0}}{3^{1 / 4}} (\frac{μ_{e}}{μ_{c}})^{1 / 2} θ_{i}^{- 1} .$

As we make quantitative comparisons between the characteristics of our derived models and those published by Murphy (1983) and by Murphy & Fiedler (1985a), below, we usually will tabulate the value of this quantity, rather than simply our derived value of $B_{0}$ .

Step 7: Identifying the Surface

Because Shrivastava's function — and, along with it, the envelope's density — drops to zero when,

$Δ = Δ_{s} \equiv π,$

we know that the radius, $ξ_{s}$ , of the bipolytropic configuration is given by the expression,

$π$	$=$	$Δ_{i} + \ln (\frac{ξ_{s}}{ξ_{i}})^{1 / 2}$
$\Rightarrow \ln (\frac{ξ_{s}}{ξ_{i}})^{1 / 2}$	$=$	$π - Δ_{i}$
$\Rightarrow ξ_{s}$	$=$	$ξ_{i} e^{2 (π - Δ_{i})} .$

In terms of the natural radial coordinate of the envelope, this is,

$η_{s} (\frac{μ_{e}}{μ_{c}})^{- 1}$

$=$

$3^{- 1 / 2} ξ_{i} e^{2 (π - Δ_{i})} .$

Examples

Normalization

The dimensionless variables used in Tables 1 & 2 are defined as follows:

$ρ^{*}$	$\equiv$	$\frac{ρ}{ρ_{0}}$	;	$r^{*}$	$\equiv$	$\frac{r}{(K_{c} / G)^{1 / 2}}$
$P^{*}$	$\equiv$	$\frac{P}{K_{c} ρ_{0}^{2}}$	;	$M_{r}^{*}$	$\equiv$	$\frac{M_{r}}{ρ_{0} (K_{c} / G)^{3 / 2}}$
$H^{*}$	$\equiv$	$\frac{H}{K_{c} ρ_{0}}$	.

Parameter Values

The $2^{n d}$ column of Table 1 catalogues the analytic expressions that define various parameters and physical properties (as identified, respectively, in column 1) of the $n_{c} = 1$ , $n_{e} = 5$ bipolytrope.

Properties of $n_{c} = 1$ , $n_{e} = 5$ , BiPolytrope Having Various Interface Locations, $ξ_{i}$
Parameter	$ξ_{i}$
$θ_{i}$	$\frac{\sin ξ_{i}}{ξ_{i}}$
$- (\frac{d θ_{i}}{d ξ})_{i}$	$\frac{1}{ξ_{i}^{2}} (\sin ξ - ξ_{i} \cos ξ_{i})$
$r_{c o r e}^{} \equiv r_{i}^{}$	$(\frac{1}{2 π})^{1 / 2} ξ_{i}$
$ρ_{i}^{} \|_{c} = (\frac{μ_{e}}{μ_{c}})^{- 1} ρ_{i}^{} \|_{e}$	$θ_{i}$
$P_{i}^{*}$	$θ_{i}^{2}$
$H_{i}^{} \|_{c} = \frac{n_{c} + 1}{n_{e} + 1} (\frac{μ_{e}}{μ_{c}}) H_{i}^{} \|_{e}$	$2 θ_{i}$
$M_{c o r e}^{*}$	$(\frac{2}{π})^{1 / 2} (\sin ξ_{i} - ξ_{i} \cos ξ_{i})$
$(\frac{μ_{e}}{μ_{c}})^{- 1} η_{i}$	$\frac{ξ_{i}}{\sqrt{3}}$
$- (\frac{d ϕ}{d η})_{i}$	$\frac{1}{\sqrt{3} θ_{i}} (- \frac{d θ}{d ξ})_{i} = \frac{1}{\sqrt{3}} (\frac{1}{ξ_{i}} - \cot ξ_{i})$
$p$	$\frac{3}{3 - 2 (μ_{e} / μ_{c}) (1 - ξ_{i} \cot ξ_{i})}$
$y_{r o o t}$	$p (1 + {1 + [1 + (p^{- 2} - 1)^{3}]^{1 / 2}}^{1 / 3} + {1 - [1 + (p^{- 2} - 1)^{3}]^{1 / 2}}^{1 / 3})$
$Δ_{i} - m π$	$\tan^{- 1} (y_{r o o t})$
$(A_{0} η)_{r o o t}$	$e^{2 Δ_{i}}$
$ξ_{s}$	$ξ_{i} e^{2 (π - Δ_{i})}$
$[\frac{A_{0}}{3^{1 / 2}} (\frac{μ_{e}}{μ_{c}})]$	$ξ_{i}^{- 1} e^{2 Δ_{i}}$
$[\frac{B_{0}}{3^{1 / 4}} (\frac{μ_{e}}{μ_{c}})^{1 / 2}]$	$[ξ_{i} (\frac{3}{\sin^{2} Δ_{i}} - 2)]^{- 1 / 2} = θ_{i} [\frac{ξ_{i}^{1 / 2}}{\sin ξ_{i}} (\frac{3}{\sin^{2} Δ_{i}} - 2)^{- 1 / 2}]$
$- (\frac{d ϕ}{d η})_{s} (\frac{μ_{e}}{μ_{c}})$	$\frac{1}{2 ξ_{i} e^{3 (π - Δ_{i})}} (\frac{3}{\sin^{2} Δ_{i}} - 2)^{1 / 2}$
$R_{s}^{*}$	$(2 π)^{- 1 / 2} ξ_{i} e^{2 (π - Δ_{i})}$
$(\frac{μ_{e}}{μ_{c}}) M_{t o t}^{*}$	$(\frac{3}{2 π})^{1 / 2} \sin ξ_{i} (\frac{3}{\sin^{2} Δ_{i}} - 2)^{1 / 2} e^{(π - Δ_{i})}$

Profile

Once the values of the key set of parameters have been determined as illustrated in the preceding formula table, the radial profile of various physical variables can be determined throughout the bipolytrope as detailed in step #4 and step #8, above. The following table summarizes the mathematical expressions that define the profile throughout the core (column 2) and throughout the envelope (column 3) of the normalized mass density, $ρ^{*} (r^{*})$ , the normalized gas pressure, $P^{*} (r^{*})$ , and the normalized mass interior to $r^{*}$ , $M_{r}^{*} (r^{*})$ . For all profiles, the relevant normalized radial coordinate is $r^{*}$ , as defined in the 2^nd row of the table. Graphical illustrations of these resulting profiles can be viewed by clicking on the thumbnail images posted in the last few columns of the table.

Table 2: Radial Profile of Various Physical Variables

Variable	Throughout the Core $0 \leq ξ \leq ξ_{i}$	Throughout the Envelope^† $η_{i} \leq η \leq η_{s}$	Plotted Profiles
Variable	Throughout the Core $0 \leq ξ \leq ξ_{i}$	Throughout the Envelope^† $η_{i} \leq η \leq η_{s}$	$ξ_{i} = 0.5$	$ξ_{i} = 1.0$	$ξ_{i} = 3.0$
$r^{*}$	$(\frac{1}{2 π})^{1 / 2} ξ$	$(\frac{μ_{e}}{μ_{c}})^{- 1} (\frac{3}{2 π})^{1 / 2} η$
$ρ^{*}$	$\frac{\sin ξ}{ξ}$	$(\frac{μ_{e}}{μ_{c}}) θ_{i} [ϕ (η)]^{5}$
$P^{*}$	$(\frac{\sin ξ}{ξ})^{2}$	$θ_{i}^{2} [ϕ (η)]^{6}$
$M_{r}^{*}$	$(\frac{2}{π})^{1 / 2} (\sin ξ - ξ \cos ξ)$	$(\frac{μ_{e}}{μ_{c}})^{- 2} (\frac{2 \cdot 3^{3}}{π})^{1 / 2} θ_{i} (- η^{2} \frac{d ϕ}{d η})$
^†In order to obtain the various envelope profiles, it is necessary to evaluate $ϕ (η)$ and its first derivative using the information presented in Step 6, above.