Latest revision as of 13:54, 20 November 2023

BiPolytrope with (n_c, n_e) = (5, 1)

This chapter very closely parallels our original analytic derivation — see also, 📚 P. P. Eggleton, J. Faulkner, & R. C. Cannon (1998, MNRAS, Vol. 298, issue 3, pp. 831 - 834) — of the structure of bipolytropes in which the core has an $n_{c} = 5$ polytropic index and the envelope has an $n_{e} = 1$ polytropic index. Our primary objective, here, is to renormalize the principal set of variables, replacing the central density with the configuration's total mass, so that the mass is held fixed along each model sequence.

From Table 1 of our original analytic derivation, we see that,

$(\frac{μ_{e}}{μ_{c}})^{2} M_{t o t}$	$=$	$𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} ρ_{0}^{- 1 / 5}$
$\Rightarrow ρ_{0}$	$=$	${𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{5},$

where,

𝓂_{s u r f}

\equiv

(\frac{2}{π})^{1 / 2} θ_{i}^{- 1} (- η^{2} \frac{d ϕ}{d η})_{s} = (\frac{2}{π})^{1 / 2} \frac{A η_{s}}{θ_{i}} .

Steps 2 & 3

Based on the discussion presented elsewhere of the structure of an isolated $n = 5$ polytrope, the core of this bipolytrope will have the following properties:

$θ (ξ) = [1 + \frac{1}{3} ξ^{2}]^{- 1 / 2} \Rightarrow θ_{i} = [1 + \frac{1}{3} ξ_{i}^{2}]^{- 1 / 2};$

$\frac{d θ}{d ξ} = - \frac{ξ}{3} [1 + \frac{1}{3} ξ^{2}]^{- 3 / 2} \Rightarrow (\frac{d θ}{d ξ})_{i} = - \frac{ξ_{i}}{3} [1 + \frac{1}{3} ξ_{i}^{2}]^{- 3 / 2} .$

The first zero of the function $θ (ξ)$ and, hence, the surface of the corresponding isolated $n = 5$ polytrope is located at $ξ_{s} = \infty$ . Hence, the interface between the core and the envelope can be positioned anywhere within the range, $0 < ξ_{i} < \infty$ .

Step 4: Throughout the core

Specify: $K_{c}$ and $ρ_{0} \Rightarrow$
$ρ$	$=$	$ρ_{0} θ^{n_{c}}$	$=$	$ρ_{0} (1 + \frac{1}{3} ξ^{2})^{- 5 / 2}$
$P$	$=$	$K_{c} ρ_{0}^{1 + 1 / n_{c}} θ^{n_{c} + 1}$	$=$	$K_{c} ρ_{0}^{6 / 5} (1 + \frac{1}{3} ξ^{2})^{- 3}$
$r$	$=$	$[\frac{(n_{c} + 1) K_{c}}{4 π G}]^{1 / 2} ρ_{0}^{(1 - n_{c}) / (2 n_{c})} ξ$	$=$	$[\frac{K_{c}}{G ρ_{0}^{4 / 5}}]^{1 / 2} (\frac{3}{2 π})^{1 / 2} ξ$
$M_{r}$	$=$	$4 π [\frac{(n_{c} + 1) K_{c}}{4 π G}]^{3 / 2} ρ_{0}^{(3 - n_{c}) / (2 n_{c})} (- ξ^{2} \frac{d θ}{d ξ})$	$=$	$[\frac{K_{c}^{3}}{G^{3} ρ_{0}^{2 / 5}}]^{1 / 2} (\frac{2 \cdot 3}{π})^{1 / 2} [ξ^{3} (1 + \frac{1}{3} ξ^{2})^{- 3 / 2}]$

Specify: $K_{c}$ and $M_{t o t} \Rightarrow$

$ρ$	$=$	${𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{5} (1 + \frac{1}{3} ξ^{2})^{- 5 / 2}$
	$=$	$(\frac{𝓂_{s u r f}}{M_{t o t}})^{5} (\frac{K_{c}}{G})^{15 / 2} (\frac{μ_{e}}{μ_{c}})^{- 10} (1 + \frac{1}{3} ξ^{2})^{- 5 / 2};$
$P$	$=$	$K_{c} {𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{6} (1 + \frac{1}{3} ξ^{2})^{- 3}$
	$=$	$(\frac{𝓂_{s u r f}}{M_{t o t}})^{6} K_{c}^{10} G^{- 9} (\frac{μ_{e}}{μ_{c}})^{- 12} (1 + \frac{1}{3} ξ^{2})^{- 3};$
$r$	$=$	${𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{- 2} [\frac{K_{c}}{G}]^{1 / 2} (\frac{3}{2 π})^{1 / 2} ξ$
	$=$	$(\frac{𝓂_{s u r f}}{M_{t o t}})^{- 2} (\frac{K_{c}}{G})^{- 5 / 2} (\frac{μ_{e}}{μ_{c}})^{4} (\frac{3}{2 π})^{1 / 2} ξ;$
$M_{r}$	$=$	${𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{- 1} [\frac{K_{c}^{3}}{G^{3}}]^{1 / 2} (\frac{2 \cdot 3}{π})^{1 / 2} [ξ^{3} (1 + \frac{1}{3} ξ^{2})^{- 3 / 2}]$
	$=$	$(\frac{M_{t o t}}{𝓂_{s u r f}}) (\frac{μ_{e}}{μ_{c}})^{2} (\frac{2 \cdot 3}{π})^{1 / 2} [ξ^{3} (1 + \frac{1}{3} ξ^{2})^{- 3 / 2}] .$

New Normalization

$\tilde{ρ}$	$\equiv$	$ρ [(\frac{K_{c}}{G})^{3 / 2} \frac{1}{M_{t o t}}]^{- 5};$
$\tilde{P}$	$\equiv$	$P [K_{c}^{- 10} G^{9} M_{t o t}^{6}];$
$\tilde{r}$	$\equiv$	$r [(\frac{K_{c}}{G})^{5 / 2} M_{t o t}^{- 2}],$
${\tilde{M}}_{r}$	$\equiv$	$\frac{M_{r}}{M_{t o t}};$
$\tilde{H}$	$\equiv$	$H [K_{c}^{- 5 / 2} G^{3 / 2} M_{t o t}] .$

After applying this new normalization, we have throughout the core,

$\tilde{ρ}$	$=$	$𝓂_{s u r f}^{5} (\frac{μ_{e}}{μ_{c}})^{- 10} (1 + \frac{1}{3} ξ^{2})^{- 5 / 2};$
$\tilde{P}$	$=$	$𝓂_{s u r f}^{6} (\frac{μ_{e}}{μ_{c}})^{- 12} (1 + \frac{1}{3} ξ^{2})^{- 3};$
$\tilde{r}$	$=$	$𝓂_{s u r f}^{- 2} (\frac{μ_{e}}{μ_{c}})^{4} (\frac{3}{2 π})^{1 / 2} ξ;$
${\tilde{M}}_{r}$	$=$	$𝓂_{s u r f}^{- 1} (\frac{μ_{e}}{μ_{c}})^{2} (\frac{2 \cdot 3}{π})^{1 / 2} [ξ^{3} (1 + \frac{1}{3} ξ^{2})^{- 3 / 2}] .$

Step 8: Throughout the envelope

Given (from above) that,

ρ_{0}

=

{𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{5},

we have throughout the envelope,

$ρ$	$=$	$ρ_{0} (\frac{μ_{e}}{μ_{c}}) θ_{i}^{5} ϕ$
	$=$	${𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{5} (\frac{μ_{e}}{μ_{c}}) θ_{i}^{5} ϕ$
	$=$	${(\frac{K_{c}}{G})^{15 / 2} M_{t o t}^{- 5}} 𝓂_{s u r f}^{5} (\frac{μ_{e}}{μ_{c}})^{- 9} θ_{i}^{5} ϕ;$
$P$	$=$	$K_{c} ρ_{0}^{6 / 5} θ_{i}^{6} ϕ^{2}$
	$=$	$K_{c} {𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{6} θ_{i}^{6} ϕ^{2}$
	$=$	${K_{c}^{10} G^{- 9} M_{t o t}^{- 6}} 𝓂_{s u r f}^{6} (\frac{μ_{e}}{μ_{c}})^{- 12} θ_{i}^{6} ϕ^{2};$
$r$	$=$	$[\frac{K_{c}}{G ρ_{0}^{4 / 5}}]^{1 / 2} (\frac{μ_{e}}{μ_{c}})^{- 1} θ_{i}^{- 2} (2 π)^{- 1 / 2} η$
	$=$	$[\frac{K_{c}}{G}]^{1 / 2} {𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{- 2} (\frac{μ_{e}}{μ_{c}})^{- 1} θ_{i}^{- 2} (2 π)^{- 1 / 2} η$
	$=$	${(\frac{K_{c}}{G})^{- 5 / 2} M_{t o t}^{2}} 𝓂_{s u r f}^{- 2} (\frac{μ_{e}}{μ_{c}})^{3} θ_{i}^{- 2} (2 π)^{- 1 / 2} η;$
$M_{r}$	$=$	$[\frac{K_{c}^{3}}{G^{3} ρ_{0}^{2 / 5}}]^{1 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} θ_{i}^{- 1} (\frac{2}{π})^{1 / 2} (- η^{2} \frac{d ϕ}{d η})$
	$=$	$[\frac{K_{c}^{3}}{G^{3}}]^{1 / 2} {𝓂_{s u r f} (\frac{K_{c}}{G})^{3 / 2} (\frac{μ_{e}}{μ_{c}})^{- 2} M_{t o t}^{- 1}}^{- 1} (\frac{μ_{e}}{μ_{c}})^{- 2} θ_{i}^{- 1} (\frac{2}{π})^{1 / 2} (- η^{2} \frac{d ϕ}{d η})$
	$=$	$M_{t o t} 𝓂_{s u r f}^{- 1} θ_{i}^{- 1} (\frac{2}{π})^{1 / 2} (- η^{2} \frac{d ϕ}{d η}) .$

Adopting the new normalization then gives,

$\tilde{ρ}$	$=$	$𝓂_{s u r f}^{5} (\frac{μ_{e}}{μ_{c}})^{- 9} θ_{i}^{5} ϕ;$
$\tilde{P}$	$=$	$𝓂_{s u r f}^{6} (\frac{μ_{e}}{μ_{c}})^{- 12} θ_{i}^{6} ϕ^{2};$
$\tilde{r}$	$=$	$𝓂_{s u r f}^{- 2} (\frac{μ_{e}}{μ_{c}})^{3} θ_{i}^{- 2} (2 π)^{- 1 / 2} η;$
${\tilde{M}}_{r}$	$=$	$𝓂_{s u r f}^{- 1} θ_{i}^{- 1} (\frac{2}{π})^{1 / 2} (- η^{2} \frac{d ϕ}{d η}) .$

Behavior of Central Density Along Equilibrium Sequence

Each equilibrium sequence will be defined as a sequence of models having the same jump in the mean-molecular weight, $μ_{e} / μ_{c}$ . Along a given sequence, we vary the location of the core/envelope interface, $ξ_{i}$ . Our desire is to analyze the behavior of the central density, while holding the total mass fixed, as the location of the interface is varied.

The central density is given by the expression,

{\tilde{ρ}}_{c}

=

$𝓂_{s u r f}^{5} (\frac{μ_{e}}{μ_{c}})^{- 10} [(1 + \frac{1}{3} ξ^{2})^{- 5 / 2}]_{ξ = 0} = 𝓂_{s u r f}^{5} (\frac{μ_{e}}{μ_{c}})^{- 10},$

where,

𝓂_{s u r f}

=

(\frac{2}{π})^{1 / 2} \frac{A η_{s}}{θ_{i}} .

In order to evaluate $𝓂_{s u r f}$ for a given specification of the interface location, $ξ_{i}$ , we need to know that,

$θ_{i}$	$=$	$(1 + \frac{1}{3} ξ_{i}^{2})^{- 1 / 2},$
$η_{i}$	$=$	$(\frac{μ_{e}}{μ_{c}}) \sqrt{3} θ_{i}^{2} ξ_{i},$
$Λ_{i}$	$=$	$\frac{ξ_{i}}{\sqrt{3}} [(\frac{μ_{e}}{μ_{c}})^{- 1} \frac{1}{θ_{i}^{2} ξ_{i}^{2}} - 1],$
$A$	$=$	$η_{i} (1 + Λ_{i}^{2})^{1 / 2},$
$η_{s}$	$=$	$\frac{π}{2} + η_{i} + \tan^{- 1} (Λ_{i}) .$

Keep in mind, as well, that,

$ν \equiv \frac{M_{c o r e}}{M_{t o t}}$	$=$	$(\frac{μ_{e}}{μ_{c}})^{2} \sqrt{3} [\frac{ξ_{i}^{3} θ_{i}^{4}}{A η_{s}}],$
$q \equiv \frac{r_{c o r e}}{R}$	$=$	$(\frac{μ_{e}}{μ_{c}}) \sqrt{3} [\frac{ξ_{i} θ_{i}^{2}}{η_{s}}] .$

Bipolytropic (5, 1) Equilibrium Sequences

Central Density versus xi_i (mu_ratio = 0.3100)

Model Pairings

Here we work in the context of the B-KB74 conjecture. We will stick with the sequence corresponding to $μ_{e} / μ_{c} = 0.31$ , and continue to examine the model pairings (B1 and B2) associated with the degenerate model (A) at $ν_{m a x}$ . Specifically …

file = Dropbox/WorkFolder/Wiki edits/Bipolytrope/Stability/qAndNuMax.xlsx --- worksheet = B-KB74 thru MinuPreparation Bipolytrope with $(n_{c}, n_{e}) = (5, 1)$ Selected Pairings along the $μ_{e} / μ_{c} = 0.31$ Sequence
Pairing	$ξ_{i}$	$Λ_{i}$	$ν$	$q$
A	$9.014959766$	$0.59835053$	$0.3372170064$	$0.0755022550$
B1	$9.12744$	$0.60069262$	$0.3372001445$	$0.0746451491$
B2	$8.90394$	$0.59610192$	$0.33720014467$	$0.0763642133$

Core						file = Dropbox/WorkFolder/Wiki edits/BiPolytrope/qAndNuMaxAug21.xlsx --- worksheet = B1renorm
$m_{r}$	B1		B2		$\frac{δ r}{r} = \frac{{\tilde{r}}_{B 1} - {\tilde{r}}_{B 2}}{2 ({\tilde{r}}_{B 1} + {\tilde{r}}_{B 2})}$
$m_{r}$	$ξ$	$\tilde{r} (m_{r})$	$ξ$	$\tilde{r} (m_{r})$
0.0	0.0	0.0	0.0	0.0	--
0.005	0.430797	0.0007299	0.430395	0.0007331	-0.00109
0.05	1.054468	0.0017865	1.053194	0.0017938	-0.00102
0.1	1.502081	0.0025449	1.499761	0.0025544	-0.00093
0.15	1.963871	0.0033273	1.959917	0.0033382	-0.00082
0.20	2.5329785	0.0042915	2.525985	0.0043023	-0.00063
0.25	3.366385	0.0057034	3.352268	0.0057097	-0.00028
0.30	5.000525	0.0084721	4.959790	0.0084477	+0.00072
0.33715	9.11445	0.015442	8.89185	0.0151449	+0.00486
0.3372001	9.12744	0.015464	8.90394	0.0151654	+0.00487

Envelope
$m_{r}$	B1		B2		$\frac{δ r}{r} = \frac{{\tilde{r}}_{B 1} - {\tilde{r}}_{B 2}}{2 ({\tilde{r}}_{B 1} + {\tilde{r}}_{B 2})}$
$m_{r}$	$η$	$\tilde{r} (m_{r})$	$η$	$\tilde{r} (m_{r})$
0.3372001	0.1703455	0.015464	0.1743134	0.0151654	+0.00487
0.35	0.3073375	0.0279002	0.309463	0.0269236	+0.00891
0.40	0.5753765	0.0522328	0.576515	0.0501574	+0.01013
0.45	0.748189	0.0679208	0.749101	0.0651726	+0.01032
0.50	0.8885645	0.0806641	0.8893695	0.0773761	+0.01040
0.55	1.0122575	0.091893	1.012999	0.088132	+0.01045
0.60	1.126297	0.1022455	1.1269968	0.0980499	+0.01047
0.65	1.2347644	0.1120922	1.2354345	0.1074841	+0.01049
0.70	1.3405518	0.1216956	1.3411998	0.1166858	+0.01051
0.75	1.4461523	0.131282	1.4467833	0.1258716	+0.01052
0.80	1.5542198	0.1410924	1.5548378	0.1352725	+0.01053
0.85	1.6683004	0.1514487	1.668908	0.1451967	+0.01054
0.90	1.794487	0.1629039	1.7950862	0.1561743	+0.01055
0.95	1.94764	0.1768072	1.9482325	0.1694982	+0.01055
1.00	2.2820704	0.2071669	2.282658	0.1985936	+0.01056

Attempt at Constructing Analytic Eigenfunction Expression

Background

In our accompanying discussion of eigenvectors associated with the radial oscillation of pressure-truncated polytropes, we derived the following,

Exact Solution to the Polytropic LAWE
$σ_{c}^{2} = 0$	and	$x_{P} \equiv \frac{3 (n - 1)}{2 n} [1 + (\frac{n - 3}{n - 1}) (\frac{1}{ξ θ^{n}}) \frac{d θ}{d ξ}] .$

Drawing on the definition of $θ (ξ)$ for n = 5 polytropes, as given in an accompanying chapter, we deduce that,

$x_{P} \|_{n = 5}$	$=$	$\frac{6}{5} [1 + \frac{1}{2} (\frac{1}{ξ θ^{5}}) \frac{d θ}{d ξ}]_{n = 5}$
	$=$	$\frac{6}{5} - \frac{3}{5 ξ} (1 + \frac{ξ^{2}}{3})^{5 / 2} \frac{ξ}{3} (1 + \frac{ξ^{2}}{3})^{- 3 / 2}$
	$=$	$\frac{6}{5} - \frac{1}{5} (1 + \frac{ξ^{2}}{3})$
	$=$	$1 - \frac{ξ^{2}}{15} .$

And, given that for n = 1 polytropes,

$θ (ξ) = \frac{\sin ξ}{ξ},$

we also find,

$x_{P} \|_{n = 1}$	$=$	$- 3 [(\frac{1}{ξ θ}) \frac{d θ}{d ξ}]_{n = 1}$
	$=$	$\frac{3}{ξ} (\frac{ξ}{\sin ξ}) [\frac{\sin ξ}{ξ^{2}} - \frac{\cos ξ}{ξ}]$
	$=$	$\frac{3}{ξ^{2}} [1 - ξ \cot ξ] .$

Core

Allowing for an overall leading scale factor, $α$ , a viable displacement function for the $(n = 5)$ core of our bipolytropic configuration is,

$\frac{x_{c o r e}}{α}$

$=$

$[1 - \frac{ξ^{2}}{15}] .$

Throughout the core, the corresponding Lagrangian radial coordinate, $\tilde{r}$ , is given by the expression,

{\tilde{r}}_{c o r e}

=

$𝓂_{s u r f}^{- 2} (\frac{μ_{e}}{μ_{c}})^{4} (\frac{3}{2 π})^{1 / 2} ξ .$

For "model A" the range is,

$0 \leq ξ \leq ξ_{i} = 9.0149598 .$

SLOPE: What is the slope of the function, $x_{c o r e} (\tilde{r})$ , at the interface?

$\frac{d x_{c o r e}}{d ξ} \|_{i}$	$=$	$- \frac{2 α ξ_{i}}{15},$
$\Rightarrow \frac{d x_{c o r e}}{d \tilde{r}} \|_{i}$	$=$	$- \frac{2 α ξ_{i}}{15} [𝓂_{s u r f}^{- 2} (\frac{μ_{e}}{μ_{c}})^{4} (\frac{3}{2 π})^{1 / 2}]^{- 1} = - 707.53765 α,$

where, for "model A," we have set $(μ_{e} / μ_{c}) = 0.31$ and $𝓂_{s u r f} = 1.938127063$ . Note as well that,

\frac{d \ln (x_{c o r e})}{d \ln \tilde{r}} |_{i} = \frac{d \ln (x_{c o r e})}{d \ln ξ} |_{i}

=

$- \frac{2 ξ_{i}^{2}}{15} [1 - \frac{ξ_{i}^{2}}{15}]^{- 1} = + 2.452697 .$

Envelope

As we have demonstrated in a separate structure discussion, the radial profile of the $(n = 1)$ envelope of our bipolytropic configuration is governed by the modified sinc-function,

$ϕ (η)$	$=$	$A [\frac{\sin (η - B)}{η}],$
$\Rightarrow - \frac{d ϕ}{d η}$	$=$	$\frac{A}{η^{2}} [\sin (η - B) - η \cos (η - B)] .$

where, for "model A," $A = 0.200812422$ and $B = - 0.859270052$ .

Again allowing for an overall leading scale factor, $β$ , a viable displacement function for the $(n = 1)$ envelope of our bipolytropic configuration is,

$\frac{x_{e n v}}{3 β}$	$=$	$\frac{1}{η ϕ} (- \frac{d ϕ}{d η})$
	$=$	$\frac{A}{η^{3}} [\sin (η - B) - η \cos (η - B)] \cdot [\frac{η}{A \sin (η - B)}]$
	$=$	$\frac{1}{η^{2}} [1 - η \cot (η - B)] .$

Throughout the envelope, the corresponding Lagrangian radial coordinate is,

${\tilde{r}}_{e n v}$

$=$

$𝓂_{s u r f}^{- 2} (\frac{μ_{e}}{μ_{c}})^{3} θ_{i}^{- 2} (2 π)^{- 1 / 2} η .$

For "model A" the range is,

$(η_{i} = 0.1723205) \leq η \leq (η_{s} = 2.282322601) .$

SLOPE: As we have detailed elsewhere, the slope of the function, $x_{e n v} (\tilde{r})$ , is related to the slope of $x_{c o r e} (\tilde{r})$ at the interface via the expression,

${\frac{d \ln x}{d \ln r} |_{i}}_{e n v} = {\frac{d \ln x}{d \ln η} |_{i}}_{e n v}$

$=$

$3 (\frac{γ_{c}}{γ_{e}} - 1) + \frac{γ_{c}}{γ_{e}} {\frac{d \ln x}{d \ln ξ} |_{i}}_{c o r e} .$

In our case, $γ_{c} = 6 / 5$ and $γ_{e} = 2 \Rightarrow γ_{c} / γ_{e} = 3 / 5$ . Hence, from the point of view of the envelope displacement function, at the interface,

$[\frac{\tilde{r}}{x_{e n v}} \cdot \frac{d x_{e n v}}{d \tilde{r}}]_{i}$	$=$	$\frac{3}{5} {[\frac{d \ln (x_{c o r e})}{d \ln ξ}]_{i} - 2}$
	$=$	$\frac{3}{5} {[2.452697 - 2} = 0.271618 .$

Now, at the interface of any bipolytrope, the ratio $\tilde{r} / x$ should have the same numerical value whether it is viewed from the point of view of the core or the envelope. Given that, for our particular "model A",

$[\frac{\tilde{r}}{x}]_{i} = \frac{0.015315}{0.00485976} = 3.15139,$

we should expect the slope of the envelope's displacement function at the interface to be,

$\frac{d x_{e n v}}{d \tilde{r}} |_{i}$

$=$

$0.08619 .$

Trial Displacement Function

The blue curve in the following figure results from plotting $x_{c o r e}$ versus ${\tilde{r}}_{c o r e}$ after setting the leading coefficient, $α = - 0.0011$ . The red-dotted curve results from plotting $(x_{e n v} + x_{s h i f t})$ versus ${\tilde{r}}_{e n v}$ after setting the leading coefficient, $β = - 0.000062$ , and $x_{s h i f t} = + 0.0105$ .

ASSESSMENT:

Our analytically specified displacement function, $x_{c o r e}$ , appears to be an excellent match to the displacement function obtained throughout the core by implementing the B-KB74 conjecture.
At first glance, the plot of (xenv+xshift) appears to provide a reasonably good fit to the approximate displacement function that we have obtained throughout the envelope by implementing the B-KB74 conjecture. But, in reality, there are two fatal flaws:
1. We have presented the behavior of our analytically specified envelope displacement function only up to the radial coordinate, $η = 2.19707 ({\tilde{r}}_{e n v} = 0.19526)$ . Between this point and the surface, $η_{s} = 2.2823226 ({\tilde{r}}_{e n v} = 0.2028415)$ — where the argument of the cotangent, $(η_{s} - B) \to π$ — the analytic function dives steeply to negative infinity. This violently departs from the behavior derived via the B-KB74 conjecture.
2. While our analytically specified displacement function, $x_{e n v}$ , satisfies the "n = 1" polytropic LAWE, this satisfaction is destroyed by adding $x_{s h i f t}$ to the displacement function.

Let's examine the slope of the displacement function at the interface. From the perspective of the core, our analytic prescription for the displacement function matches the K-BK74-derived displacement function very well. An analytic evaluation of the slope at the inferface — as derived above — gives,

$\frac{d x_{c o r e}}{d \tilde{r}} |_{i} = - 707.53765 α = + 0.77829$ .

The black-dashed line segment that appears in the following figure has this slope and goes through the point of intersection; it appears to be tangent to the analytic displacement function, as expected. Alternatively, the orange-dashed line segment that appears in this same figure, also goes through the point of intersection, but it has a slope that matches our expectation for the envelope's displacement function; that is, it has a slope as derived of,

$\frac{d x_{e n v}}{d \tilde{r}} |_{i} = + 0.08619$ .

This orange-dashed line segment does not appear to lie tangent to the K-BK74-derived displacement function for the envelope.

Trial Analytic Eigenfunction with Intersection Slopes

2^nd Trial

The relevant LAWE for the envelope is,

$[\frac{A \sin (η - B)}{η}] \frac{d^{2} x}{d η^{2}}$	$=$	$- \frac{2 A}{η} {\sin (η - B) + η \cos (η - B)} \frac{1}{η} \cdot \frac{d x}{d η} + \frac{2 A}{η} {\sin (η - B) - η \cos (η - B)} \frac{x}{η^{2}} - 2 (\frac{σ_{c}^{2}}{12}) x$
$\Rightarrow \frac{1}{3 β} \cdot \frac{d^{2} x}{d η^{2}}$	$=$	$- \frac{2}{η} {1 + η \cot (η - B)} [\frac{1}{3 β} \cdot \frac{d x}{d η}] + 2 {1 - η \cot (η - B)} \frac{x}{3 β η^{2}} - 2 (\frac{σ_{c}^{2}}{12}) [\frac{η}{3 β A \sin (η - B)}] x .$

Here, we will guess a displacement function, $x_{e n v}$ , of the form,

$\frac{x_{e n v}}{3 β}$

$=$

$\frac{1}{η^{2}} [1 - η \cot (η - B_{x})] = \frac{1}{η^{2}} - \frac{\cos (η - B_{x})}{η \sin (η - B_{x})},$

where we will assume, quite generally, that $B_{x} \neq B$ . The first and second derivatives of $x_{e n v}$ are,

$\frac{1}{3 β} [\frac{d x_{e n v}}{d η}]$	$=$	$- \frac{2}{η^{3}} + \frac{\cos (η - B_{x})}{η^{2} \sin (η - B_{x})} + \frac{\sin (η - B_{x})}{η \sin (η - B_{x})} + \frac{\cos^{2} (η - B_{x})}{η \sin^{2} (η - B_{x})}$
	$=$	$- \frac{2}{η^{3}} + \frac{1}{η} + \frac{\cos (η - B_{x})}{η^{2} \sin (η - B_{x})} + \frac{\cos^{2} (η - B_{x})}{η \sin^{2} (η - B_{x})};$
$\frac{1}{3 β} [\frac{d^{2} x_{e n v}}{d η^{2}}]$	$=$	$\frac{6}{η^{4}} - \frac{1}{η^{2}} - \frac{2 \cos (η - B_{x})}{η^{3} \sin (η - B_{x})} + \frac{1}{η^{2}} [- \frac{\sin (η - B_{x})}{\sin (η - B_{x})} - \frac{\cos^{2} (η - B_{x})}{\sin^{2} (η - B_{x})}] - \frac{\cos^{2} (η - B_{x})}{η^{2} \sin^{2} (η - B_{x})} + \frac{1}{η} [- \frac{2 \cos (η - B_{x})}{\sin (η - B_{x})} - \frac{2 \cos^{3} (η - B_{x})}{\sin^{3} (η - B_{x})}]$
	$=$	$\frac{6}{η^{4}} - \frac{1}{η^{2}} - \frac{2 \cos (η - B_{x})}{η^{3} \sin (η - B_{x})} - \frac{1}{η^{2}} [1 + \frac{\cos^{2} (η - B_{x})}{\sin^{2} (η - B_{x})}] - \frac{\cos^{2} (η - B_{x})}{η^{2} \sin^{2} (η - B_{x})} - \frac{1}{η} [\frac{2 \cos (η - B_{x})}{\sin (η - B_{x})} + \frac{2 \cos^{3} (η - B_{x})}{\sin^{3} (η - B_{x})}]$
	$=$	$\frac{6}{η^{4}} - \frac{2}{η^{2}} - \frac{2 \cos (η - B_{x})}{η^{3} \sin (η - B_{x})} - \frac{2}{η^{2}} [\frac{\cos^{2} (η - B_{x})}{\sin^{2} (η - B_{x})}] - \frac{2}{η} [\frac{\cos (η - B_{x})}{\sin (η - B_{x})} + \frac{\cos^{3} (η - B_{x})}{\sin^{3} (η - B_{x})}]$
	$=$	$\frac{6}{η^{4}} - \frac{2}{η^{2}} [1 + \cot^{2} (η - B_{x})] - \frac{2 \cot (η - B_{x})}{η^{3}} - \frac{2}{η} [\cot (η - B_{x}) + \cot^{3} (η - B_{x})] .$

These match the expressions for $d x_{P} / d η$ and $d^{2} x_{P} / d η^{2}$ that we separately derived in a subsection labeled Attempt_4B of an accompanying discussion labeled. Plugging these three relations into the LAWE, then multiplying through by $η^{4}$ , gives,

$\frac{6}{η^{4}} - \frac{2}{η^{2}} [1 + \cot^{2} (η - B_{x})] - \frac{2 \cot (η - B_{x})}{η^{3}} - \frac{2}{η} [\cot (η - B_{x}) + \cot^{3} (η - B_{x})]$	$=$	$- \frac{2}{η} {1 + η \cot (η - B)} [- \frac{2}{η^{3}} + \frac{1}{η} + \frac{\cot (η - B_{x})}{η^{2}} + \frac{\cot^{2} (η - B_{x})}{η}]$
		$+ {2 [1 - η \cot (η - B)] \frac{1}{η^{2}} - 2 (\frac{σ_{c}^{2}}{12}) [\frac{η}{A \sin (η - B)}]} [\frac{1}{η^{2}} - \frac{\cot (η - B_{x})}{η}]$
$\Rightarrow 6 - 2 η^{2} [1 + \cot^{2} (η - B_{x})] - 2 η \cot (η - B_{x}) - 2 η^{3} [\cot (η - B_{x}) + \cot^{3} (η - B_{x})]$	$=$	$- 2 {1 + η \cot (η - B)} [- 2 + η^{2} + η \cot (η - B_{x}) + η^{2} \cot^{2} (η - B_{x})]$
		$+ {2 [1 - η \cot (η - B)] - 2 (\frac{σ_{c}^{2}}{12}) [\frac{η^{3}}{A \sin (η - B)}]} [1 - η \cot (η - B_{x})]$

$\Rightarrow (\frac{σ_{c}^{2}}{6}) [\frac{η^{3}}{A \sin (η - B)}] [1 - η \cot (η - B_{x})]$	$=$	$[1 + η \cot (η - B)] [4 - 2 η^{2} - 2 η \cot (η - B_{x}) - 2 η^{2} \cot^{2} (η - B_{x})]$
		$+ 2 [1 - η \cot (η - B)] [1 - η \cot (η - B_{x})] - 6 + 2 η^{2} [1 + \cot^{2} (η - B_{x})] + 2 η \cot (η - B_{x}) + 2 η^{3} [\cot (η - B_{x}) + \cot^{3} (η - B_{x})]$
	$=$	$[4 - 2 η^{2} - 2 η \cot (η - B_{x}) - 2 η^{2} \cot^{2} (η - B_{x})] + η \cot (η - B) [4 - 2 η^{2} - 2 η \cot (η - B_{x}) - 2 η^{2} \cot^{2} (η - B_{x})]$
		$+ [2 - 2 η \cot (η - B) - 2 η \cot (η - B_{x}) + 2 η^{2} \cot (η - B) \cot (η - B_{x})] - 6 + 2 η^{2} + 2 η^{2} \cot^{2} (η - B_{x}) + 2 η \cot (η - B_{x}) + 2 η^{3} \cot (η - B_{x}) + 2 η^{3} \cot^{3} (η - B_{x})$
	$=$	$- 2 η \cot (η - B_{x}) - 2 η^{2} \cot^{2} (η - B_{x}) + 4 η \cot (η - B) - 2 η^{3} \cot (η - B) - 2 η^{2} \cot (η - B) \cot (η - B_{x}) - 2 η^{3} \cot (η - B) \cot^{2} (η - B_{x})$
		$- 2 η \cot (η - B) - 2 η \cot (η - B_{x}) + 2 η^{2} \cot (η - B) \cot (η - B_{x}) + 2 η^{2} \cot^{2} (η - B_{x}) + 2 η \cot (η - B_{x}) + 2 η^{3} \cot (η - B_{x}) + 2 η^{3} \cot^{3} (η - B_{x})$
	$=$	$- 2 η^{3} [\cot (η - B) + \cot (η - B) \cot^{2} (η - B_{x}) - \cot (η - B_{x}) - \cot^{3} (η - B_{x})] + 2 η [\cot (η - B) - \cot (η - B_{x})]$

Notice that if we set $B_{x} = B$ , the RHS of this LAWE expression goes to zero. This [thankfully] is as expected.

Numerical Integration Through Envelope

In an effort to numerically determine the eigenfunction of the envelope, we will follow the procedure described in an accompanying stability analysis of pressure-truncated polytropes to integrate the $n = 1$ envelope from the core/envelope interface to the surface. In a closely related chapter titled, Radial Oscillations of n = 1 Polytropic Spheres, we have tried to find analytic expressions for the eigenvector of marginally unstable configurations.

Setup

Continuous Form of LAWE

We begin by writing our generic version of the polytropic LAWE,

	$0 = \frac{d^{2} x}{d ξ^{2}} + [4 - (n + 1) Q] \frac{1}{ξ} \cdot \frac{d x}{d ξ} + (n + 1) [(\frac{σ_{c}^{2}}{6 γ_{g}}) \frac{ξ^{2}}{θ} - α Q] \frac{x}{ξ^{2}}$
where: $Q (ξ) \equiv - \frac{d \ln θ}{d \ln ξ},$ $σ_{c}^{2} \equiv \frac{3 ω^{2}}{2 π G ρ_{c}},$ and, $α \equiv (3 - \frac{4}{γ_{g}})$

then focus on the $n = 1$ case — setting $γ_{g} = 1 + 1 / n = 2$ and $α = + 1$ — the relevant LAWE becomes,

0

=

$\frac{d^{2} x}{d η^{2}} + {4 - 2 Q} \frac{1}{η} \cdot \frac{d x}{d η} + 2 {(\frac{σ_{c}^{2}}{12}) \frac{η^{2}}{ϕ} - Q} \frac{x}{η^{2}},$

📚 Chatterji (1951) — STEP 1

If we focus on the $n = 1$ case but leave $γ$ (and, hence, $α$ ) unspecified, the relevant LAWE becomes,

0

=

$\frac{d^{2} x}{d η^{2}} + {4 - 2 Q} \frac{1}{η} \cdot \frac{d x}{d η} + 2 {(\frac{σ_{c}^{2}}{6 γ}) \frac{η^{2}}{ϕ} - α Q} \frac{x}{η^{2}} .$

If, in addition, we make the notation substitutions,

Q

\to

$\frac{μ}{n + 1} = \frac{μ}{2}$

and,

\frac{σ_{c}^{2}}{3 γ}

\to

$ω_{C h a t t e r j i}^{2},$

the relevant LAWE becomes,

$0$	$=$	$\frac{d^{2} x}{d η^{2}} + {4 - μ} \frac{1}{η} \cdot \frac{d x}{d η} + {(\frac{σ_{c}^{2}}{3 γ}) \frac{η^{2}}{ϕ} - α μ} \frac{x}{η^{2}}$
	$=$	$\frac{d^{2} x}{d η^{2}} + [\frac{4 - μ}{η}] \frac{d x}{d η} + [\frac{ω_{C h a t t e r j i}^{2}}{ϕ} - \frac{α μ}{η^{2}}] x,$

which, apart from notation, is identical to equation (1) of 📚 Chatterji (1951).

Now, in the broadest context,

$ϕ (η)$	$=$	$A [\frac{\sin (η - B)}{η}],$
$- \frac{d ϕ}{d η}$	$=$	$\frac{A}{η^{2}} [\sin (η - B) - η \cos (η - B)],$
$\Rightarrow Q (η) \equiv - \frac{d \ln ϕ}{d \ln η}$	$=$	$\frac{A}{η^{2}} [\sin (η - B) - η \cos (η - B)] \cdot \frac{η^{2}}{A \sin (η - B)}$
	$=$	$[1 - η \cot (η - B)] .$

📚 Chatterji (1951) — STEP 2

In the context of an isolated, $n = 1$ polytrope, the appropriate parameter values are, $A = 1$ and $B = 0$ , in which case,

$ϕ (η)$

$=$

$\frac{\sin η}{η},$

and,

$μ = 2 Q$

$=$

$2 (1 - η \cot η),$

and the relevant LAWE becomes,

$0$	$=$	$\frac{d^{2} x}{d η^{2}} + [\frac{4 + 2 (η \cot η - 1)}{η}] \frac{d x}{d η} + [\frac{η ω_{C h a t t e r j i}^{2}}{\sin η} + \frac{2 α (η \cot η - 1)}{η^{2}}] x$
	$=$	$\frac{d^{2} x}{d η^{2}} + [\frac{2 (1 + η \cot η)}{η}] \frac{d x}{d η} + [\frac{η ω_{C h a t t e r j i}^{2}}{\sin η} + \frac{2 α (η \cot η - 1)}{η^{2}}] x,$

which, again apart from notation, is identical to equation (2) of 📚 Chatterji (1951); see also the (unnumbered) equation in the middle of the left-hand-column of p. 223 in 📚 Murphy & Fiedler (1985b).

If we set $γ = (n + 1) / n = 2$ (and correspondingly set $α = [3 - 4 / γ] = + 1)$ , the $n = 1$ LAWE we becomes,

$0$	$=$	$\frac{d^{2} x}{d η^{2}} + {4 - 2 [1 - η \cot (η - B)]} \frac{1}{η} \cdot \frac{d x}{d η} + 2 {(\frac{σ_{c}^{2}}{12}) \frac{η^{3}}{A \sin (η - B)} - [1 - η \cot (η - B)]} \frac{x}{η^{2}}$
	$=$	$\frac{d^{2} x}{d η^{2}} + 2 {1 + η \cot (η - B)} \frac{1}{η} \cdot \frac{d x}{d η} + 2 {(\frac{σ_{c}^{2}}{12}) \frac{η^{3}}{A \sin (η - B)} - 1 + η \cot (η - B)} \frac{x}{η^{2}} .$

Multiplying through by $ϕ$ , we can write,

[\frac{A \sin (η - B)}{η}] \frac{d^{2} x}{d η^{2}}

=

$- \frac{2 A}{η} {\sin (η - B) + η \cos (η - B)} \frac{1}{η} \cdot \frac{d x}{d η} + \frac{2 A}{η} {\sin (η - B) - η \cos (η - B)} \frac{x}{η^{2}} - 2 (\frac{σ_{c}^{2}}{12}) x .$

Discrete Form of LAWE

In order to integrate this 2^nd-order ODE numerically, we will build from the more general expression for polytropes used in our separate development of a finite-difference scheme, namely,

$θ_{i} {x_{i}}^{″}$

$=$

$- [4 θ_{i} - (n + 1) ξ_{i} (- θ^{'})_{i}] \frac{{x_{i}}^{'}}{ξ_{i}} - (n + 1) [\frac{σ_{c}^{2}}{6 γ_{g}} - \frac{α}{ξ_{i}} (- θ^{'})_{i}] x_{i} .$

Making the notation substitutions, $(ξ, θ) \to (η, ϕ)$ , we have instead,

$ϕ_{i} {x_{i}}^{″}$

$=$

$- [4 ϕ_{i} - (n + 1) η_{i} (- ϕ^{'})_{i}] \frac{{x_{i}}^{'}}{η_{i}} - (n + 1) [\frac{σ_{c}^{2}}{6 γ_{g}} - \frac{α}{η_{i}} (- ϕ^{'})_{i}] x_{i} .$

Now, adopting the finite-difference expressions,

${x_{i}}^{'}$	$\approx$	$\frac{x_{+} - x_{-}}{2 Δ_{η}},$ and,
${x_{i}}^{″}$	$\approx$	$\frac{x_{+} - 2 x_{i} + x_{-}}{Δ_{η}^{2}},$

the discrete form of the LAWE becomes,

$x_{+} \overset{T E R M 1}{\overset{⏞}{[2 ϕ_{i} + \frac{4 Δ_{η} ϕ_{i}}{η_{i}} - Δ_{η} (n + 1) (- ϕ^{'})_{i}]}}$

$=$

$x_{-} \overset{T E R M 2}{\overset{⏞}{[\frac{4 Δ_{η} ϕ_{i}}{η_{i}} - Δ_{η} (n + 1) (- ϕ^{'})_{i} - 2 ϕ_{i}]}} + x_{i} \overset{T E R M 3}{\overset{⏞}{{4 ϕ_{i} - \frac{Δ_{η}^{2} (n + 1)}{3} [\frac{σ_{c}^{2}}{γ_{g}} - 2 α (- \frac{3 ϕ^{'}}{η})_{i}]}}} .$

When applied specifically to an $n = 1$ , polytropic configuration, we should insert the following specific expressions:

$γ_{g}$	$=$	$1 + \frac{1}{n} = 2,$
$α$	$=$	$3 - \frac{4}{γ_{g}} = + 1,$
$ϕ_{i}$	$=$	$A [\frac{\sin (η_{i} - B)}{η_{i}}],$
$(- ϕ^{'})_{i}$	$=$	$\frac{A}{η_{i}^{2}} [\sin (η_{i} - B) - η_{i} \cos (η_{i} - B)] .$

Pressure-Truncated n = 1 Polytrope

In the case of an isolated $n = 1$ polytrope, we must set $B = 0$ ; in addition, it is customary to set $A = 1$ . The relevant LAWE is, then,

0

=

$\frac{d^{2} x}{d η^{2}} + 2 {1 + η \cot (η)} \frac{1}{η} \cdot \frac{d x}{d η} + 2 {(\frac{σ_{c}^{2}}{12}) \frac{η^{3}}{\sin (η)} - 1 + η \cot (η)} \frac{x}{η^{2}} .$

Review of Trial Analytic Eigenfunction

This is the same 2^nd-order ODE that we derived in a separate discussion; there it was accompanied by the surface boundary condition,

$- \frac{d \ln x}{d \ln ξ} \|_{s u r f}$	=	$(\frac{3 - n}{n + 1}) + \frac{n σ_{c}^{2}}{6 (n + 1)} [\frac{ξ}{θ^{'}}]_{s u r f}$
$\Rightarrow - \frac{d \ln x}{d \ln η} \|_{s u r f}$	=	$1 + \frac{σ_{c}^{2}}{12} [\frac{η^{3}}{(η \cos η - \sin η)}]_{η = π} = 1 - \frac{π^{2} σ_{c}^{2}}{12} .$

From, for example, a separate succinct demonstration, we appreciate that if the displacement function is assumed to be,

$x_{P}$

$=$

$\frac{3}{η^{2}} [1 - η \cot η]$

… that is,

$x_{P}$

$=$

$\frac{3}{η^{2}} - \frac{3 \cos η}{η \sin η},$

in which case,

$\frac{d x_{P}}{d η}$

$=$

$- \frac{6}{η^{3}} + 3 [\frac{\cos η}{η^{2} \sin η} + \frac{1}{η} + \frac{\cos^{2} η}{η \sin^{2} η}],$

and,

$\frac{d^{2} x_{P}}{d η^{2}}$	$=$	$+ \frac{18}{η^{4}} + 3 \frac{d}{d η} [\frac{\cos η}{η^{2} \sin η}] + 3 \frac{d}{d η} [\frac{1}{η}] + 3 \frac{d}{d η} [\frac{\cos^{2} η}{η \sin^{2} η}]$
	$=$	$+ \frac{18}{η^{4}} - 3 [\frac{2 \cos η}{η^{3} \sin η} + \frac{\cos^{2} η}{η^{2} \sin^{2} η} + \frac{\sin η}{η^{2} \sin η}] - [\frac{3}{η^{2}}] - 3 [\frac{\cos^{2} η}{η^{2} \sin^{2} η} + \frac{2 \cos^{3} η}{η \sin^{3} η} + \frac{2 \cos η}{η \sin η}] .$

Hence,

LAWE	$=$	${\frac{2}{η} + \frac{2 \cos η}{\sin η}} {- \frac{6}{η^{3}} + [\frac{3 \cos η}{η^{2} \sin η} + \frac{3}{η} + \frac{3 \cos^{2} η}{η \sin^{2} η}]} + 2 {(\frac{σ_{c}^{2}}{12}) \frac{η^{3}}{\sin (η)} - 1 + \frac{η \cos η}{\sin η}} [\frac{3}{η^{4}} - \frac{3 \cos η}{η^{3} \sin η}]$
		$+ \frac{18}{η^{4}} - 3 [\frac{2 \cos η}{η^{3} \sin η} + \frac{\cos^{2} η}{η^{2} \sin^{2} η} + \frac{\sin η}{η^{2} \sin η}] - [\frac{3}{η^{2}}] - 3 [\frac{\cos^{2} η}{η^{2} \sin^{2} η} + \frac{2 \cos^{3} η}{η \sin^{3} η} + \frac{2 \cos η}{η \sin η}]$
	$=$	$[\frac{2}{η} + 2 \cot η] [- \frac{6}{η^{3}} + \frac{3 \cot η}{η^{2}} + \frac{3}{η} + \frac{3 \cot^{2} η}{η}] + {(\frac{σ_{c}^{2}}{6}) \frac{η^{3}}{\sin η}} [\frac{3}{η^{4}} - \frac{3 \cot η}{η^{3}}] + [- 2 + 2 η \cot η] [\frac{3}{η^{4}} - \frac{3 \cot η}{η^{3}}]$
		$+ \frac{18}{η^{4}} - [\frac{6 \cot η}{η^{3}} + \frac{3 \cot^{2} η}{η^{2}} + \frac{3}{η^{2}}] - [\frac{3}{η^{2}}] - [\frac{3 \cot^{2} η}{η^{2}} + \frac{6 \cot^{3} η}{η} + \frac{6 \cot η}{η}]$
	$=$	${(\frac{σ_{c}^{2}}{2}) \frac{1}{η \sin η}} [1 - η \cot η] + [- \frac{12}{η^{4}} + \frac{6}{η^{2}}] + [2 \cot η] [\frac{3}{η^{3}} + \frac{3 \cot η}{η^{2}}] + [2 \cot η] [- \frac{6}{η^{3}} + \frac{3 \cot η}{η^{2}} + \frac{3}{η} + \frac{3 \cot^{2} η}{η}]$
		$+ [- \frac{6}{η^{4}} + \frac{6 \cot η}{η^{3}}] + [2 \cot η] [\frac{3}{η^{3}} - \frac{3 \cot η}{η^{2}}] + \frac{18}{η^{4}} - \frac{6}{η^{2}} + [2 \cot η] [- \frac{3 \cot^{2} η}{η} - \frac{3 \cot η}{η^{2}} - \frac{3}{η} - \frac{3}{η^{3}}]$
	$=$	${(\frac{σ_{c}^{2}}{2}) \frac{1}{η \sin η}} [1 - η \cot η] + [2 \cot η] [- \frac{3}{η^{3}} + \frac{6 \cot η}{η^{2}} + \frac{3}{η} + \frac{3 \cot^{2} η}{η}]$
		$+ [2 \cot η] [\frac{3}{η^{3}} - \frac{3 \cot^{2} η}{η} - \frac{6 \cot η}{η^{2}} - \frac{3}{η}]$
	$=$	${(\frac{σ_{c}^{2}}{2}) \frac{1}{η \sin η}} [1 - η \cot η] .$

the $n = 1$ LAWE reduces to …

LAWE

=

${(\frac{σ_{c}^{2}}{2}) \frac{1}{η \sin η}} [1 - η \cot η] .$

ASSESSMENT:

If we set $σ_{c}^{2} = 0$ , the right-hand-side of this expression goes to zero — and, hence, the $n = 1$ LAWE is satisfied — for any chosen truncation radius in the range, $0 < η_{i} < π$ . (We have not included the isolated $n = 1$ polytrope because $x_{P}$ blows up at its surface, $η_{i} = π$ .)

At the surface,

η_{i}

, the slope of this trial eigenfunction is,

$\frac{1}{3} \cdot \frac{d x_{P}}{d η} |_{i}$

$=$

$[\frac{\cot η_{i}}{η_{i}^{2}} + \frac{1}{η_{i}} + \frac{\cot^{2} η_{i}}{η_{i}}] - \frac{2}{η_{i}^{3}} .$

By contrast, as stated above, the eigenvalue problem will be properly solved only if the surface slope is,

$- \frac{d \ln x}{d \ln η} \|_{s u r f}$	=	$1 + \frac{{σ_{c}^{2}}^{0}}{12} [\frac{η^{3}}{(η \cos η - \sin η)}]_{η = π} = 1$
$\Rightarrow \frac{1}{3} \cdot \frac{d x_{P}}{d η} \|_{s u r f}$	=	$- \frac{x_{P}}{3 η} \|_{i}$
	=	$- \frac{1}{η_{i}^{3}} [1 - η_{i} \cot η_{i}] = \frac{\cot η_{i}}{η_{i}^{2}} - \frac{1}{η_{i}^{3}} .$

These two slopes do not appear to be the same, for any allowed choice of $η_{i}$ . We conclude, therefore, that no model along the sequence of pressure-truncated $n = 1$ polytropes is marginally unstable.

Determining Discrete Representation of Eigenfunction

Let's numerically integrate the discrete form of the $n = 1$ LAWE over the radial coordinate range, $0 \leq η_{i} \leq η_{s}$ . Following our discussion of the more general polytropic case, we will kickstart integration from the center, outward, via the expression,

$x_{2}$

$=$

$x_{1} [1 - \frac{(n + 1) 𝔉 Δ_{η}^{2}}{60}],$

where,

$𝔉$

$\equiv$

$[\frac{σ_{c}^{2}}{γ_{g}} - 2 α] .$

Here, we will restrict our investigation to the case where $γ_{g} = (n + 1) / n = 2$ , in which case, $α = (3 - 4 / γ_{g}) = + 1$ , $𝔉 = (σ_{c}^{2} - 4) / 2$ , and

$x_{2}$

$=$

$x_{1} [1 - \frac{(σ_{c}^{2} - 4) Δ_{η}^{2}}{60}] .$

EXAMPLE: $A = 1$ , $B = 0$ , $Δ_{η} = π / 99 = 0.031733259$ ; evaluated over range, $0 \leq η_{i} \leq π$ .

$σ_{c}^{2}$	$𝔉$	$x_{2}$	$ϕ_{2}$	$(- ϕ^{'})_{2}$	TERM1	TERM2	TERM3	$x_{3}$
5	+0.5	0.999983217	0.999832175	0.010576686	5.998321784	1.998993085	3.998992898	0.999932829

Isolated n = 1 Polytrope

If we integrate all the way out to the natural, zero-pressure surface of our $n = 1$ polytrope, then $η_{s} = π$ and — as derived in our discussion of the equilibrium structure of n = 1 polytropes — $(ρ_{c} / \bar{ρ}) = π^{2} / 3$ . In line with our discussion of Schwarzschild's model of oscillations in $n = 3$ polytropes, we therefore expect the boundary condition at the surface of our $n = 1$ configurations to be given by the expression,

$- \frac{d \ln x}{d \ln η} \|_{s u r f}$	$=$	$- \frac{1}{2} {[𝔉 + 2 α] (\frac{ρ_{c}}{\bar{ρ}}) - 2 α}$
	$=$	$1 - (\frac{σ_{c}^{2} π^{2}}{12}),$

as reviewed immediately above.

📚 Chatterji (1951) — STEP 3

Here we examine what the boundary condition should be at the surface of an isolated $n = 1$ polytrope. Given that, quite generally in the context of isolated polytropes,

$α$

$=$

$3 - \frac{4}{γ},$

and,

$𝔉$

$=$

$\frac{σ_{c}^{2}}{γ} - 2 α,$

the surface boundary condition is,

$- \frac{d \ln x}{d \ln η} \|_{s u r f}$	$=$	$- \frac{1}{2} {[𝔉 + 2 α] (\frac{ρ_{c}}{\bar{ρ}}) - 2 α}$
	$=$	$- \frac{σ_{c}^{2}}{2 γ} (\frac{ρ_{c}}{\bar{ρ}}) + 3 - \frac{4}{γ}$
	$=$	$3 - \frac{1}{γ} [4 + \frac{σ_{c}^{2}}{2} (\frac{ρ_{c}}{\bar{ρ}})] .$

Considerations:

For an isolated $n = 1$ polytrope, the central-to-mean density is, $ρ_{c} / \bar{ρ} = π^{2} / 3$ . Hence,

${- \frac{d \ln x}{d \ln η} |_{s u r f}}_{n = 1}$ $=$
$3 - \frac{1}{γ} [4 + \frac{π^{2} σ_{c}^{2}}{6}] .$
If, in addition, we set $γ = (n + 1) / n = 2 \Rightarrow α = + 1$ , then,

${- \frac{d \ln x}{d \ln η} |_{s u r f}}_{n = 1, α = + 1}$ $=$
$3 - \frac{1}{2} [4 + \frac{π^{2} σ_{c}^{2}}{6}] = 1 - \frac{π^{2} σ_{c}^{2}}{12} .$
If we set $γ = [4 / (3 - α)]$ for all other values of $α$ , we can write,

${- \frac{d \ln x}{d \ln η} |_{s u r f}}_{n = 1, α}$ $=$
$3 - (3 - α) [1 + \frac{π^{2} σ_{c}^{2}}{24}] = α - (3 - α) [\frac{π^{2} σ_{c}^{2}}{24}] .$

At the bottom of p. 469 of his article, 📚 Chatterji (1951) states that, "… the condition for the Node to fall at the surface of the star is,

3 f + z \frac{d f}{d z}

=

$0,$

which we interpret to mean,

{- \frac{d \ln f}{d \ln z} |_{s u r f}}_{n = 1, α}

=

$3 .$

He goes on to say, "As the adiabatic approximation breaks down near the boundary we have not strictly followed this condition."

This should be compared with the finite-difference representation of the logarithmic derivative, namely,

$+ \frac{Δ \ln x}{Δ \ln ξ} |_{s u r f a c e}$

$\approx$

$\frac{ξ_{m a x}}{x_{N}} [\frac{x_{N + 1} - x_{N - 1}}{2 Δ_{ξ}}] .$

CAUTION! Because, for each guess of $σ_{c}^{2}$ , the eigenfunction climbs (or plummets) rapidly as we approach the surface, in practice we evaluated the finite-difference representation of the logarithmic derivative at a zone location that is a bit inside of the actual surface; for example, when we divided the equilibrium configuration into $N = 100$ grid zones, we evaluated the "surface" derivative at zone number 97.

Here we have adopted an analysis that closely resembles our discussion of the analysis of $n = 3$ polytropes that was published by 📚 Schwarzschild (1941). Here we have divided our model into $N = 100$ radial zones and, using this algorithm, integrated the LAWE from the center of the configuration to the surface, for $α = + 1$ , and approximately 40 different chosen values of the frequency parameter across the range, $- 2 \leq 𝔉 \leq + 18$ . The radial displacement functions resulting from these integrations are presented in the following figure as an animation sequence. The specified value of $𝔉$ is displayed at the top of each animation frame, and the resulting displacement function, $x (η)$ , is traced by the small, red circular markers in each frame.

file = Dropbox/WorkFolder/Wiki edits/BiPolytrope/qAndNuMaxAug21.xlsx --- worksheet = n1Oscillations Four Modes of Oscillation of an Isolated, $n = 1$ Polytrope
Mode	$σ_{c}^{2}$	Neg. Slope $1 - (σ_{c}^{2} π^{2} / 12)$	$𝔉 = \frac{σ_{c}^{2}}{γ_{g}} - 2 α$
Fundamental	2.2405295	3.1287618	-0.879735
1^st Overtone	6.340767	-32.06757	1.1703835
2^nd Overtone	13.694927	-153.2545	4.8474635
3^rd Overtone	28.462829	-665.3074	12.231415
file = Dropbox/WorkFolder/Wiki edits/LinearPerturbation/n1Eigenvectors/MovieFrames/KeyAnimation/n1osc06.gif

L. D. Chatterji (1951)
Radial Oscillations of a Gaseous Star of Polytropic Index I
Publication of the Indian National Science Academy, Vol. 17, No. 6, pp. 467 - 470

Amplitudes and frequencies of the displacement functions for three modes, assuming

α = 0.6

and

γ = 5 / 3

Amplitudes extracted from Chatterji's Table II (p. 468)

Plot for comparison with Chatterji's Fig. 1 (p. 469)

Eigenfrequencies extracted
from Chatterji's Table I (p. 468)

                                  1st            2nd
Abscissa	Fundamental	Overtone	Overtone
0.0	         1.000000	1.000000	1.000000
0.1	         1.000169	0.998882	0.996820
0.2	         1.000677	0.995518	0.987281
0.3	         1.001525	0.989874	0.971386
0.4	         1.002716	0.981890	0.949136
0.5	         1.004251	0.971495	0.920555
0.6	         1.006143	0.958596	0.885671
0.7	         1.008389	0.943052	0.844515
0.8	         1.011009	0.924713	0.797168
0.9	         1.014006	0.903389	0.743728
1.0	         1.017390	0.878859	0.684350
1.1	         1.021175	0.850865	0.619257
1.2	         1.025374	0.819105	0.548757
1.3	         1.030004	0.783221	0.473277
1.4	         1.035102	0.742868	0.393396
1.5	         1.040853	0.697654	0.309941
1.6	         1.047084	0.646920	0.223844
1.7	         1.053810	0.590042	0.136419
1.8	         1.061066	0.526318	0.049379
1.9	         1.068886	0.454939       -0.035065
2.0	         1.077309	0.374974       -0.114079
2.1	         1.086374	0.285357       -0.184050
2.2	         1.096138	0.184876       -0.240444
2.3	         1.106766	0.072271       -0.277903
2.4	         1.118204      -0.054152       -0.288854
2.5	         1.130496      -0.196154       -0.264401
2.6	         1.143708      -0.355598       -0.193931
2.7	         1.157893      -0.534282       -0.065351
2.8	         1.173099      -0.733397	0.133422
2.9	         1.189288      -0.951614	0.408698
3.0	         1.206063      -1.175893	0.734701
3.1	         1.218532      -1.251806	0.780444

Mode	$ω_{C h a t t e r j i}^{2}$	$σ_{c}^{2}$
Fundamental	0.231	1.155
1^st Overtone	1.517	7.585
2^nd Overtone	3.580	17.900

The solid circular markers in the plot (center panel) show how the amplitude of the displacement function varies with radius $0 \leq η < π$ for three separate radial modes, according to the data provided in Table II of 📚 Chatterji (1951), which has been reproduced here in the scrollable left-hand panel. In the plot, blue is the fundamental mode, red is the 1^st overtone, green is the 2^nd overtone. The (square of the) eigenfrequency corresponding to each mode, according to Table I of 📚 Chatterji (1951), is provided in the column of the right-hand panel that is (highlighted in pink and) labeled $ω_{C h a t t e r j i}^{2}$ ; also listed are the corresponding values of $σ_{c}^{2} = 3 γ ω_{C h a t t e r j i}^{2}$ .

The smooth, solid curves in the middle-panel plot are not fits to Chatterji's data. Rather, they result from our own, independent numerical integration of the relevant LAWE, assuming that Chatterji's published values of the (square of the) eigenfrequency are correct for all three modes. In all three cases for the specified eigenfrequency, there is excellent agreement between our determination of the radial eigenfunction and the determination obtained by 📚 Chatterji (1951).

We are exceptionally pleased to find that, for each of the three modes of oscillation, the displacement function obtained via our integration of the LAWE (solid curves in the figure) runs through the discrete points recorded by 📚 Chatterji (1951) (solid circular markers in the figure). But in doing so, we find from our higher resolution model that there is an inflection point just inside the surface of the model; this is not the smooth behavior that is expected as the surface is approached. In an effort to correct this behavior, we have changed the constraint that is applied while integrating the LAWE from the center, outward: Instead of forcing $ω_{C h a t t e r j i}^{2}$ to match the value published by 📚 Chatterji (1951), we have let the value of this oscillation frequency vary while enforcing the surface boundary condition describe above as CONSIDERATION "C". The resulting "improved" solution is shown in the figure that follows.

Our Imposed Surface Boundary Condition:

{- \frac{d \ln x}{d \ln η} |_{s u r f}}_{n = 1, α}

=

$α - (3 - α) [\frac{π^{2} σ_{c}^{2}}{24}] .$

Amplitudes and frequencies of the displacement functions for three modes, assuming

α = 0.6

and

γ = 5 / 3

Amplitudes determined from our numerical integration of the LAWE

Our version of Chatterji's Fig. 1

Eigenfrequencies determined from our integration

Abscissa	Fundamental	1st Overtone	2nd Overtone
0.000000000	1.000000000	 1.000000000	 1.000000000
0.031733259	1.000047844	 0.999943498	 0.999786141
0.063466518	1.000089016	 0.999601959	 0.998867632
0.095199777	1.000174709	 0.999061021	 0.997382877
0.126933037	1.000294726	 0.998302963	 0.995304066
0.158666296	1.000449107	 0.997327028	 0.992631032
0.190399555	1.000637906	 0.996132244	 0.989363571
0.222132814	1.000861191	 0.994717421	 0.985501447
0.253866073	1.001119039	 0.993081149	 0.981044389
0.285599332	1.001411544	 0.991221792	 0.975992105
0.317332591	1.001738809	 0.989137492	 0.970344285
0.34906585	1.002100951	 0.986826157	 0.964100608
0.38079911	1.002498098	 0.984285466	 0.957260757
0.412532369	1.002930394	 0.981512860     0.949824425
0.444265628	1.003397993	 0.978505538	 0.94179133
0.475998887	1.003901064	 0.975260454	 0.933161228
0.507732146	1.004439786	 0.971774312	 0.923933924
0.539465405	1.005014356	 0.968043557	 0.914109296
0.571198664	1.005624981	 0.964064374	 0.903687306
0.602931923	1.006271884	 0.959832677	 0.892668024
0.634665183	1.006955299	 0.955344103	 0.881051648
0.666398442	1.007675478	 0.950594005	 0.868838527
0.698131701	1.008432684	 0.945577446	 0.856029188
0.72986496	1.009227198	 0.940289184	 0.842624363
0.761598219	1.010059312	 0.934723671	 0.828625017
0.793331478	1.010929336	 0.928875035	 0.814032388
0.825064737	1.011837596	 0.922737076	 0.798848013
0.856797996	1.01278443	 0.916303251	 0.783073774
0.888531256	1.013770197	 0.909566661	 0.766711937
0.920264515	1.01479527	 0.902520043	 0.749765195
0.951997774	1.015860038	 0.895155752	 0.732236722
0.983731033	1.016964908	 0.887465751	 0.714130222
1.015464292	1.018110307	 0.879441592	 0.695449985
1.047197551	1.019296676	 0.8710744	 0.676200956
1.07893081	1.020524478	 0.862354861	 0.656388792
1.110664069	1.021794193	 0.853273198	 0.636019943
1.142397329	1.023106322	 0.843819155	 0.615101726
1.174130588	1.024461383	 0.833981977	 0.593642407
1.205863847	1.025859919	 0.82375039	 0.5716513
1.237597106	1.027302491	 0.813112573	 0.549138858
1.269330365	1.028789682	 0.802056142	 0.526116785
1.301063624	1.030322099	 0.790568118	 0.502598146
1.332796883	1.03190037	 0.778634906	 0.478597499
1.364530142	1.033525148	 0.766242261	 0.454131023
1.396263402	1.035197111	 0.753375263	 0.429216666
1.427996661	1.03691696	 0.740018284	 0.403874305
1.45972992	1.038685425	 0.726154954	 0.378125913
1.491463179	1.04050326	 0.711768126	 0.351995745
1.523196438	1.042371249	 0.696839839	 0.325510537
1.554929697	1.044290203	 0.681351278	 0.298699722
1.586662956	1.046260964	 0.665282732	 0.271595661
1.618396215	1.048284403	 0.64861355	 0.244233898
1.650129475	1.050361424	 0.631322093	 0.216653434
1.681862734	1.052492964	 0.613385687	 0.188897019
1.713595993	1.054679993	 0.594780567	 0.161011472
1.745329252	1.056923518	 0.575481822	 0.133048033
1.777062511	1.059224581	 0.555463336	 0.105062731
1.80879577	1.061584262	 0.534697725	 0.077116794
1.840529029	1.064003681	 0.513156272	 0.049277088
1.872262289	1.066484	 0.490808851	 0.021616595
1.903995548	1.069026422	 0.467623859	-0.005785076
1.935728807	1.071632194	 0.443568129	-0.032841123
1.967462066	1.074302612	 0.418606853	-0.059456951
1.999195325	1.077039017	 0.392703483	-0.085529513
2.030928584	1.079842802	 0.365819646	-0.110946599
2.062661843	1.082715411	 0.337915031	-0.135586067
2.094395102	1.085658345	 0.308947292	-0.159315006
2.126128362	1.08867316	 0.278871926	-0.181988834
2.157861621	1.091761474	 0.247642155	-0.203450318
2.18959488	1.094924965	 0.215208794	-0.223528513
2.221328139	1.098165381	 0.181520118	-0.242037616
2.253061398	1.101484536	 0.146521711	-0.258775724
2.284794657	1.104884319	 0.110156314	-0.273523491
2.316527916	1.108366697	 0.072363659	-0.286042681
2.348261175	1.111933717	 0.033080298	-0.296074601
2.379994435	1.115587515	-0.007760587	-0.303338425
2.411727694	1.11933032	-0.050229374	-0.307529379
2.443460953	1.12316446	-0.094400211	-0.308316806
2.475194212	1.127092372	-0.140351229	-0.305342096
2.506927471	1.131116609	-0.188164774	-0.298216493
2.53866073	1.135239852	-0.237927637	-0.286518776
2.570393989	1.139464924	-0.289731302	-0.269792846
2.602127248	1.143794808	-0.343672193	-0.247545241
2.633860508	1.148232666	-0.39985192	-0.219242641
2.665593767	1.152781872	-0.458377516	-0.184309461
2.697327026	1.157446048	-0.519361653	-0.142125667
2.729060285	1.162229122	-0.582922804	-0.092025093
2.760793544	1.167135405	-0.649185328	-0.033294642
2.792526803	1.172169712	-0.718279394	 0.034824895
2.824260062	1.17733755	-0.790340637	 0.113135186
2.855993321	1.18264542	-0.865509304	 0.202471616
2.887726581	1.188101346	-0.943928474	 0.303685139
2.91945984	1.193715839	-1.025740391	 0.417605887
2.951193099	1.199503802	-1.111078809	 0.54496891
2.982926358	1.205488688	-1.200051936	 0.686253524
3.014659617	1.2117128	-1.292700149	 0.841298052
3.046392876	1.21826791	-1.388871861	 1.008209416
3.078126135	1.225416475	-1.487741753	 1.179292479
3.109859394	1.234427405	-1.584566325	 1.314705175

Mode	$ω_{C h a t t e r j i}^{2}$	$σ_{c}^{2}$
Fundamental	0.2298579	1.1492896
1^st Overtone	1.4733124	7.366562
2^nd Overtone	3.3484654	16.742327

The solid circular markers in the plot (center panel) show how the amplitude of the displacement function varies with radius $0 \leq η < π$ for three separate radial modes, according to the data provided in Table II of 📚 Chatterji (1951), which has been reproduced here in the scrollable left-hand panel. In the plot, blue is the fundamental mode, red is the 1^st overtone, green is the 2^nd overtone. The (square of the) eigenfrequency corresponding to each mode, according to Table I of 📚 Chatterji (1951), is provided in the column of the right-hand panel that is (highlighted in pink and) labeled $ω_{C h a t t e r j i}^{2}$ ; also listed are the corresponding values of $σ_{c}^{2} = 3 γ ω_{C h a t t e r j i}^{2}$ .

The smooth, solid curves in the middle-panel plot are not fits to Chatterji's data. Rather, they result from our own, independent numerical integration of the relevant LAWE, assuming that Chatterji's published values of the (square of the) eigenfrequency are correct for all three modes. In all three cases for the specified eigenfrequency, there is excellent agreement between our determination of the radial eigenfunction and the determination obtained by 📚 Chatterji (1951).

Pressure-Truncated n = 1 Polytrope

Drawing from an accompanying discussion, if the polytropic configuration is truncated by the pressure, $P_{e}$ , of a hot, tenuous external medium, then the solution to the LAWE is subject to the outer boundary condition,

$- \frac{d \ln x}{d \ln η}$

$=$

$3$ at $η = \tilde{η}$ .

Bipolytropic Envelope (Trial Simplification)

For the $n = 1$ envelope of a $(n_{c}, n_{e}) = (5, 1)$ bipolytrope, the relevant LAWE is,

LAWE	$=$	$\frac{d^{2} x}{d η^{2}}$
		$+ 2 {1 + \frac{η \cos (η - B)}{\sin (η - B)}} \frac{1}{η} \cdot \frac{d x}{d η}$
		$+ 2 {(\frac{σ_{c}^{2}}{12}) \frac{η^{3}}{A \sin (η - B)} - 1 + \frac{η \cos (η - B)}{\sin (η - B)}} \frac{x}{η^{2}} .$

Three terms in this expression blow up at the surface, where $(η - B) \to π$ and, hence, $\sin (η - B) \to 0$ . We can improve the behavior of this LAWE expression by assuming that the eigenfunction is of the form,

x

=

$f (η) [\sin (η - B)]^{m},$

in which case,

$\frac{d x}{d η}$	$=$	$[\sin (η - B)]^{m} \frac{d f}{d η} + m f (η) [\sin (η - B)]^{m - 1} \cos (η - B);$ and,
$\frac{d^{2} x}{d η^{2}}$	$=$	$[\sin (η - B)]^{m} \frac{d^{2} f}{d η^{2}} + 2 m [\sin (η - B)]^{m - 1} \cos (η - B) \cdot \frac{d f}{d η} + m (m - 1) f (η) [\sin (η - B)]^{m - 2} \cos^{2} (η - B) - m f (η) [\sin (η - B)]^{m - 1} \sin (η - B) .$

This gives,

LAWE	$=$	$[\sin (η - B)]^{m} \frac{d^{2} f}{d η^{2}} + 2 m [\sin (η - B)]^{m - 1} \cos (η - B) \cdot \frac{d f}{d η} + m (m - 1) f (η) [\sin (η - B)]^{m - 2} \cos^{2} (η - B) - m f (η) [\sin (η - B)]^{m - 1} \sin (η - B)$
		$+ 2 {1 + \frac{η \cos (η - B)}{\sin (η - B)}} \frac{1}{η} \cdot {[\sin (η - B)]^{m} \frac{d f}{d η} + m f (η) [\sin (η - B)]^{m - 1} \cos (η - B)}$
		$+ 2 {(\frac{σ_{c}^{2}}{12}) \frac{η}{A \sin (η - B)} - \frac{1}{η^{2}} + \frac{\cos (η - B)}{η \sin (η - B)}} f (η) [\sin (η - B)]^{m}$
	$=$	$[\sin (η - B)]^{m} \frac{d^{2} f}{d η^{2}} + 2 {\frac{1}{η} + \frac{\cos (η - B)}{\sin (η - B)}} [\sin (η - B)]^{m} \frac{d f}{d η} + 2 m [\sin (η - B)]^{m - 1} \cos (η - B) \cdot \frac{d f}{d η}$
		$+ m (m - 1) [\sin (η - B)]^{m - 2} \cos^{2} (η - B) \cdot f (η) - m [\sin (η - B)]^{m - 1} \sin (η - B) \cdot f (η)$
		$+ 2 m {\frac{1}{η} + \frac{\cos (η - B)}{\sin (η - B)}} [\sin (η - B)]^{m - 1} \cos (η - B) \cdot f (η) + 2 {(\frac{σ_{c}^{2}}{12}) \frac{η}{A \sin (η - B)} - \frac{1}{η^{2}} + \frac{\cos (η - B)}{η \sin (η - B)}} [\sin (η - B)]^{m} f (η)$
	$=$	$[\sin (η - B)]^{m} \frac{d^{2} f}{d η^{2}} + 2 {\frac{1}{η} [\sin (η - B)] + (m + 1) \cos (η - B)} [\sin (η - B)]^{m - 1} \frac{d f}{d η}$
		$+ {m (m - 1) \cos^{2} (η - B) - m [\sin (η - B)]^{2}} [\sin (η - B)]^{m - 2} \cdot f (η)$
		$+ {\frac{2 m}{η} [\sin (η - B)] \cos (η - B) + 2 m \cos^{2} (η - B) + [(\frac{σ_{c}^{2}}{6}) \frac{η}{A}] [\sin (η - B)] - \frac{2}{η^{2}} [\sin (η - B)]^{2} + \frac{2 \cos (η - B)}{η} [\sin (η - B)]} [\sin (η - B)]^{m - 2} \cdot f (η) .$

Try m = 1 and m = 2

If we set $m = 1$ , there are still terms in the LAWE expression that blow up at the surface, where $(η - B) \to π$ and, hence, $\sin (η - B) \to 0$ . Instead, let's try $m = 2$ :

$L A W E \|_{m = 2}$	$=$	$[\sin (η - B)]^{2} \frac{d^{2} f}{d η^{2}} + 2 {\frac{1}{η} [\sin (η - B)] + 3 \cos (η - B)} [\sin (η - B)] \frac{d f}{d η}$
		$+ {2 \cos^{2} (η - B) - 2 [\sin (η - B)]^{2}} \cdot f (η)$
		$+ {\frac{4}{η} [\sin (η - B)] \cos (η - B) + 4 \cos^{2} (η - B) + [(\frac{σ_{c}^{2}}{6}) \frac{η}{A}] [\sin (η - B)] - \frac{2}{η^{2}} [\sin (η - B)]^{2} + \frac{2 \cos (η - B)}{η} [\sin (η - B)]} \cdot f (η),$

which, at the surface $η \to η_{s} = (π + B)$ , reduces to …

{L A W E |_{m = 2}}_{η_{s}}

=

$6 f (η_{s}) .$

Hence, this LAWE will be satisfied for any function, $f (η)$ , that goes to zero at the surface.

Try m = 3

Setting $m = 3$ , we obtain,

$L A W E \|_{m = 3}$	$=$	$[\sin (η - B)]^{3} \frac{d^{2} f}{d η^{2}} + 2 {\frac{1}{η} [\sin (η - B)] + 4 \cos (η - B)} [\sin (η - B)]^{2} \frac{d f}{d η}$
		$+ {6 \cos^{2} (η - B) - 3 [\sin (η - B)]^{2}} [\sin (η - B)] \cdot f (η)$
		$+ {\frac{6}{η} [\sin (η - B)] \cos (η - B) + 6 \cos^{2} (η - B) + [(\frac{σ_{c}^{2}}{6}) \frac{η}{A}] [\sin (η - B)] - \frac{2}{η^{2}} [\sin (η - B)]^{2} + \frac{2 \cos (η - B)}{η} [\sin (η - B)]} [\sin (η - B)] \cdot f (η) .$

which trivially reduces to zero at the surface because, $η \to η_{s} = (π + B) \Rightarrow \sin (η - B) \to 0$ . For all other relevant radial positions in the envelope, $η_{i} \leq η < η_{s}$ , we can divide through by $\sin^{3} (η - B)$ to obtain,

[\sin (η - B)]^{- 3} \times L A W E |_{m = 3}

=

$\frac{d^{2} f}{d η^{2}} + 2 {\frac{1}{η} + 4 \cot (η - B)} \cdot \frac{d f}{d η} + {12 \cot^{2} (η - B) - 3 + \frac{8}{η} [\cot (η - B)] + [(\frac{σ_{c}^{2}}{6}) \frac{η}{A \sin (η - B)}] - \frac{2}{η^{2}}} \cdot f (η),$

Boundary Condition

In addition, there is a (boundary condition) constraint on the slope of the eigenfunction at the surface. So, let's examine …

$\frac{d \ln x}{d \ln η} \|_{m = 2} \equiv [\frac{η}{x} \cdot \frac{d x}{d η}]_{m = 2}$	$=$	$\frac{η}{f (η) \sin^{2} (η - B)} {\sin^{2} (η - B) \frac{d f}{d η} + 2 f (η) \sin (η - B) \cos (η - B)}$
	$=$	$\frac{d \ln f}{d \ln η} + 2 η \cot (η - B)$

Now, from above, we appreciate that when $ϕ = A \sin (η - B) / η$ ,

$η \cot (η - B)$	$=$	$1 + \frac{d \ln ϕ}{d \ln ξ}$
$\Rightarrow \frac{d \ln x}{d \ln η} \|_{m = 2}$	$=$	$\frac{d \ln f}{d \ln η} + 2 [1 + \frac{d \ln ϕ}{d \ln ξ}] .$

It therefore appears as though we should adopt the function relation,

\frac{d \ln f}{d \ln η}

=

$- 2 \frac{d \ln ϕ}{d \ln η}$

x

=

$f (η) [\sin (η - B)]^{m},$

Let's now examine "model A" from above, for which, $A = 0.200812422$ and $B = - 0.859270052$ . If we set $σ_{c}^{2} = 0$ , this LAWE becomes,

0

=

$\frac{d^{2} x}{d η^{2}} + [4 - 2 Q] \frac{1}{η} \cdot \frac{d x}{d η} - 2 [α Q] \frac{x}{η^{2}} .$

Discrete Determination of Bipolytropic Envelope

Here we focus on the specific $(n_{c}, n_{e}) = (5, 1)$ equilibrium model sequence that has $(μ_{e} / μ_{c}) = 0.31$ ; and along this sequence, we attempt to analyze the dynamical stability of "model A" from above, which sits along the sequence at the maximum-core-mass turning point for which …

$(n_{c}, n_{e}) = (5, 1)$ and $(μ_{e} / μ_{c}) = 0.31$
Model	$A$	$B$	$ξ_{i}$	$θ_{i} = (1 + ξ_{i}^{2} / 3)^{- 1 / 2}$	$η_{i} = 3^{1 / 2} (\frac{μ_{e}}{μ_{c}}) ξ_{i} θ_{i}^{2}$	$η_{s} = B + π$	$𝓂_{s u r f} = (\frac{2}{π})^{1 / 2} \frac{A η_{s}}{θ_{i}}$
A	0.200812422	- 0.859270052	9.0149598	0.188679805	0.17232050	2.28232260	1.9381270

Key Parameter-Parameter Ratios
$\frac{ξ}{\tilde{r}} = (\frac{2 π}{3})^{1 / 2} 𝓂_{s u r f}^{2} (\frac{μ_{e}}{μ_{c}})^{- 4}$	$\frac{η}{\tilde{r}} = 𝓂_{s u r f}^{2} (\frac{μ_{e}}{μ_{c}})^{- 3} θ_{i}^{2} (2 π)^{1 / 2}$	$\frac{η}{ξ}$
588.6362811	11.25175286	0.019114950

As presented above, when $σ_{c}^{2} = 0$ , the eigenfunction for the core that we have deduced via the B-KB74 conjecture appears to be well represented by the expressions,

$x_{c o r e}$

$=$

$C_{0} [1 - \frac{ξ^{2}}{15}],$ and, $\frac{d x}{d ξ} |_{c o r e} = - \frac{2 C_{0} ξ}{15},$ with, $C_{0} = - 0.0011,$

over the radial-parameter range, $0 \leq ξ \leq ξ_{i} .$

At the Core/Envelope Interface (as viewed from the core)
$x_{i}$	$\frac{d x}{d ξ} \|_{i}$	${\tilde{r}}_{i}$	$\frac{d x}{d \tilde{r}} \|_{i}$	$[\frac{d \ln x}{d \ln ξ}]_{i} = [\frac{d \ln x}{d \ln \tilde{r}}]_{i}$
+ 0.004859763	+ 0.001322194	0.015314992	+ 0.778291359	+ 2.4526969

Copying from our earlier discussion of the envelope for "model A", the range of the radial parameter is,

$(η_{i} = 0.1723205) \leq η \leq (η_{s} = 2.282322601) .$

SLOPE: As we have detailed elsewhere, we expect that the slope of the function, $x_{e n v} (\tilde{r})$ , is related to the slope of $x_{c o r e} (\tilde{r})$ at the interface via the expression,

${\frac{d \ln x}{d \ln r} |_{i}}_{e n v} = {\frac{d \ln x}{d \ln η} |_{i}}_{e n v}$

$=$

$3 (\frac{γ_{c}}{γ_{e}} - 1) + \frac{γ_{c}}{γ_{e}} {\frac{d \ln x}{d \ln ξ} |_{i}}_{c o r e} .$

In our case, $γ_{c} = 6 / 5$ and $γ_{e} = 2 \Rightarrow γ_{c} / γ_{e} = 3 / 5$ . Hence, from the point of view of the envelope displacement function, at the interface,

$[\frac{\tilde{r}}{x_{e n v}} \cdot \frac{d x_{e n v}}{d \tilde{r}}]_{i}$	$=$	$\frac{3}{5} {[\frac{d \ln (x_{c o r e})}{d \ln ξ}]_{i} - 2}$
	$=$	$\frac{3}{5} {[2.452697 - 2} = 0.271618 .$

Now, at the interface of any bipolytrope, the ratio $\tilde{r} / x$ should have the same numerical value whether it is viewed from the point of view of the core or the envelope. Given that, for our particular "model A",

$[\frac{\tilde{r}}{x}]_{i} = \frac{0.015315}{0.00485976} = 3.15139,$

we should expect the slope of the envelope's displacement function at the interface to be,

$\frac{d x_{e n v}}{d \tilde{r}} |_{i}$

$=$

$0.08619 .$

As above, we will integrate the discrete LAWE outward using the finite-difference expression,

$x_{+} \overset{T E R M 1}{\overset{⏞}{[2 ϕ_{i} + \frac{4 Δ_{η} ϕ_{i}}{η_{i}} - Δ_{η} (n + 1) (- ϕ^{'})_{i}]}}$

$=$

$x_{-} \overset{T E R M 2}{\overset{⏞}{[\frac{4 Δ_{η} ϕ_{i}}{η_{i}} - Δ_{η} (n + 1) (- ϕ^{'})_{i} - 2 ϕ_{i}]}} + x_{i} \overset{T E R M 3}{\overset{⏞}{{4 ϕ_{i} - \frac{Δ_{η}^{2} (n + 1)}{3} [\frac{σ_{c}^{2}}{γ_{g}} - 2 α (- \frac{3 ϕ^{'}}{η})_{i}]}}} .$

When we started the integration at the center of the configuration, we kickstarted the process by, first, setting $x_{1} = 1$ ; then, second, setting,

$x_{2}$

$=$

$x_{1} [1 - \frac{(n + 1) 𝔉 Δ_{η}^{2}}{60}],$

where,

$𝔉$

$\equiv$

$[\frac{σ_{c}^{2}}{γ_{g}} - 2 α] .$

Having obtained $x_{1} \to x_{-}$ and $x_{2} \to x_{i}$ , we then used the finite-difference expression to calculate $x_{+} \to x_{3}$ , as well as all subsequent " $x_{+}$ " values, all the way to the surface.

Here, instead, we want to start the envelope integration at the core/envelope interface as follows:

The displacement function for the core gives us the value of the displacement function, $x_{i} = + 0.004859763$ , at $ξ_{i} = 9.0149598$ , that is, at $η_{i} = 0.17232050$ ; we recognize that this value of $x_{i}$ (at the interface) also furnishes the value of $x_{i}$ in the first integration step of the finite-difference expressions.
We will then "guess" the slope of the envelope's displacement function, $q \equiv [d x / d η]_{i}$ , at the interface.
Our discrete representation of this first derivative permits us to write,

$q$

$\approx$

$\frac{x_{+} - x_{-}}{2 Δ_{η}}$

$\Rightarrow x_{-}$

$\approx$

$x_{+} - 2 q Δ_{η} .$

Inserting this expression into the finite-difference approximation to the LAWE gives for the first integration step only!

$x_{+} \cdot T E R M 1$

$=$

$(x_{+} - 2 q Δ_{η}) \cdot T E R M 2 + x_{i} \cdot T E R M 3$

$\Rightarrow x_{+} \cdot [T E R M 1 - T E R M 2]$

$=$

$x_{i} \cdot T E R M 3 - 2 q Δ_{η} \cdot T E R M 2 .$

NOTE: Judging by the behavior of the B-KB74 generated displacement function, at the interface we expect the slope, $[d \ln x / d \ln \tilde{r}]_{e n v}$ , from the envelope's perspective to be shallower than the slope, $[d \ln x / d \ln \tilde{r}]_{c o r e}$ , from the core's perspective. That is to say, we expect to "guess" values of $q$ such that at the interface,

$0$	$<$	$[\frac{d \ln x}{d \ln \tilde{r}}]_{c o r e} - [\frac{d \ln x}{d \ln \tilde{r}}]_{e n v}$
$\Rightarrow [\frac{d \ln x}{d \ln \tilde{r}}]_{e n v}$	$<$	$[\frac{d \ln x}{d \ln \tilde{r}}]_{c o r e}$
$\Rightarrow [\frac{d \ln x}{d \ln η}]_{e n v}$	$<$	$[\frac{d \ln x}{d \ln \tilde{r}}]_{c o r e}$
$\Rightarrow [\frac{η}{x} \cdot \frac{d x}{d η}]_{e n v}$	$<$	$[\frac{d \ln x}{d \ln \tilde{r}}]_{c o r e}$
$\Rightarrow [\frac{d x}{d η}]_{e n v}$	$<$	$\frac{x_{i}}{η_{i}} \cdot [\frac{d \ln x}{d \ln \tilde{r}}]_{c o r e}$
$\Rightarrow q$	$<$	$[\frac{+ 0.004859763}{+ 0.1723205}] \cdot 2.4526969 = + 0.06917068 .$

Examine Pressure Gradient at the Interface

Determine the interface-pressure-gradient from two different perspectives: (1) Look at the behavior of the pressure as determined when the hydrostatic-balance models have been constructed; and (2) Look at the behavior of the specific entropy at the interface.

From Hydrostatic Balance

Pressure Gradient at Core Interface

Step 4: Throughout the core … we have,

$P^{*} \equiv \frac{P}{[K_{c} ρ_{0}^{6 / 5}]}$	$=$	$(1 + \frac{1}{3} ξ^{2})^{- 3}$
$\Rightarrow \frac{d P^{*}}{d ξ}$	$=$	$- 2 ξ (1 + \frac{1}{3} ξ^{2})^{- 4};$

and,

$r^{*} \equiv [\frac{G ρ_{0}^{4 / 5}}{K_{c}}] r$	$=$	$(\frac{3}{2 π})^{1 / 2} ξ$
$\Rightarrow \frac{ξ}{r^{*}}$	$=$	$(\frac{2 π}{3})^{1 / 2} .$

Hence, from the perspective of the core, at the interface $(ξ_{i})$ the radial pressure derivative is,

$\frac{d P^{*}}{d r^{*}} |_{i}$

$=$

$- 2 ξ_{i} (1 + \frac{1}{3} ξ_{i}^{2})^{- 4} (\frac{2 π}{3})^{1 / 2} .$

Note, as well, that,

$[\frac{r^{}}{P^{}} \cdot \frac{d P^{}}{d r^{}}]_{i}$	$=$	$- 2 ξ_{i} (1 + \frac{1}{3} ξ_{i}^{2})^{- 4} (\frac{2 π}{3})^{1 / 2} [(\frac{3}{2 π})^{1 / 2} ξ_{i}] (1 + \frac{1}{3} ξ_{i}^{2})^{3}$
	$=$	$- 2 ξ_{i}^{2} (1 + \frac{1}{3} ξ_{i}^{2})^{- 1} .$

Pressure Gradient at Envelope Interface

Step 8: Throughout the envelope … we have,

$P^{*} \equiv \frac{P}{[K_{c} ρ_{0}^{6 / 5}]}$	$=$	$θ_{i}^{6} ϕ^{2} = A^{2} [1 + \frac{ξ_{i}^{2}}{3}]^{- 3} [\frac{\sin (η - B)}{η}]^{2}$
$\Rightarrow \frac{d P^{*}}{d η}$	$=$	$2 A^{2} [1 + \frac{ξ_{i}^{2}}{3}]^{- 3} [\frac{\sin (η - B)}{η}] {\frac{\cos (η - B)}{η} - \frac{\sin (η - B)}{η^{2}}};$

and,

$r^{*} \equiv [\frac{G ρ_{0}^{4 / 5}}{K_{c}}] r$	$=$	$(\frac{μ_{e}}{μ_{c}})^{- 1} θ_{i}^{- 2} (2 π)^{- 1 / 2} η$
$\Rightarrow \frac{η}{r^{*}}$	$=$	$(\frac{μ_{e}}{μ_{c}}) θ_{i}^{2} (2 π)^{1 / 2} .$

Hence, from the perspective of the envelope, at the interface $(η_{i})$ the radial pressure derivative is,

$\frac{d P^{*}}{d r^{*}} |_{i}$

$=$

$(\frac{μ_{e}}{μ_{c}}) (2^{3} π)^{1 / 2} A^{2} [1 + \frac{ξ_{i}^{2}}{3}]^{- 4} [\frac{\sin (η_{i} - B)}{η_{i}^{2}}] {η_{i} \cos (η_{i} - B) - \sin (η_{i} - B)},$

where,

$A$

$=$

$\frac{η_{i}}{\sin (η_{i} - B)},$

and,

$η_{i}$

$=$

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

Simplifying this last expression a bit, we have,

$\frac{d P^{}}{d r^{}} \|_{i}$	$=$	$(\frac{μ_{e}}{μ_{c}}) (2^{3} π)^{1 / 2} [1 + \frac{ξ_{i}^{2}}{3}]^{- 4} [η_{i} \cot (η_{i} - B) - 1]$
	$=$	$- 2 ξ_{i} (\frac{2 π}{3})^{1 / 2} (1 + \frac{ξ_{i}^{2}}{3})^{- 4} {1 - η_{i} \cot (η_{i} - B)} (\frac{μ_{e}}{μ_{c}}) \frac{\sqrt{3}}{ξ_{i}} .$

Note, as well, that,

$[\frac{r^{}}{P^{}} \cdot \frac{d P^{}}{d r^{}}]_{i}$	$=$	$(\frac{μ_{e}}{μ_{c}}) (2^{3} π)^{1 / 2} A^{2} [1 + \frac{ξ_{i}^{2}}{3}]^{- 4} [\frac{\sin (η_{i} - B)}{η_{i}^{2}}] {η_{i} \cos (η_{i} - B) - \sin (η_{i} - B)}$
		$\times (\frac{μ_{e}}{μ_{c}})^{- 1} θ_{i}^{- 2} (2 π)^{- 1 / 2} η_{i} {A^{2} [1 + \frac{ξ_{i}^{2}}{3}]^{- 3} [\frac{\sin (η_{i} - B)}{η_{i}}]^{2}}^{- 1}$
	$=$	$2 [1 + \frac{ξ_{i}^{2}}{3}]^{- 1} {η_{i} \cot (η_{i} - B) - 1} θ_{i}^{- 2} η_{i}$
	$=$	$- 2 ξ_{i}^{2} (1 + \frac{ξ_{i}^{2}}{3})^{- 1} {1 - η_{i} \cot (η_{i} - B)} \frac{3^{1 / 2}}{ξ_{i}} (\frac{μ_{e}}{μ_{c}}) .$

Pressure Gradient Summary

Whether viewed from the perspective of the core or the envelope, we have shown that the pressure at the interface is the same. However, at the interface, the first derivative (or the logarithmic derivative) of the pressure as viewed from the envelope is "larger" than what is viewed from the perspective of the core by the following factor:

factor

$=$

${1 - η_{i} \cot (η_{i} - B)} \frac{\sqrt{3}}{ξ_{i}} (\frac{μ_{e}}{μ_{c}}) .$

We note, for later use, that averaging these two pressure-gradients at the interface gives,

$\frac{1}{2} {[\frac{r^{*}}{P^{*}} \cdot \frac{d P^{*}}{d r^{*}}]_{c o r e} + [\frac{r^{*}}{P^{*}} \cdot \frac{d P^{*}}{d r^{*}}]_{e n v}}_{i}$

$=$

$- ξ_{i} (1 + \frac{1}{3} ξ_{i}^{2})^{- 1} {ξ_{i} + [1 - η_{i} \cot (η_{i} - B)] 3^{1 / 2} (\frac{μ_{e}}{μ_{c}})} .$

From Step-Function Behavior of Specific Entropy

Strategically Incorporate Step Function

As we have discussed separately, a useful expression for the specific entropy of any individual Lagrangian fluid element is,

$\frac{s}{ℜ}$

$=$

$\frac{1}{μ (γ - 1)} \cdot \ln (\frac{P}{ρ^{γ}}) .$

How does $s / ℜ$ vary as a function of the Lagrangian mass shell (or Lagrangian radial coordinate)? In the case of a spherical bipolytropic configuration: $s = s_{c}$ (a constant) throughout the core; $s = s_{e}$ (another constant) throughout the envelope; and a unit step function,

$H (ζ) = {\begin{cases} 0; & ζ < 0 \\ 1; & ζ > 0 \end{cases}$

[MF53], Part I, §2.1 (p. 123), Eq. (2.1.6)

can be introduced to accomplish the instantaneous jump from $s_{c}$ to $s_{e}$ at the core/envelope interface. Specifically, after defining,

$ζ$

$\equiv$

$\frac{r}{r_{i}} - 1,$

we obtain the correct physical description of the variation of specific entropy with mass shell, $m$ , via the expression,

$s (ζ)$

$=$

$s_{c} + H (ζ) \cdot (s_{e} - s_{c}) .$

Adopting the half-maximum convention — which states that $H (ζ = 0) = \frac{1}{2}$ — we acknowledge that the functional value of the specific entropy at the interface is, $s_{i} = \frac{1}{2} (s_{c} + s_{e})$ . Also, from our accompanying brief discussion of the behavior of the unit step function, we appreciate that,

$\frac{d H (ζ)}{d ζ}$

$=$

$δ (ζ),$

where, $δ (ζ)$ is the Dirac delta function. We conclude, therefore, that precisely at the interface,

$\frac{d s (ζ)}{d ζ} |_{i}$

$=$

$[(s_{e} - s_{c}) \cdot δ (ζ)]_{i} = (s_{e} - s_{c}) .$

Generally speaking, the two parameters, $μ, γ$ , and the mass density, $ρ$ , also will exhibit a step-function behavior at the interface of each equilibrium bipolytrope. The following table summarizes how we model the radial variation of these quantities.

Quantity	Functional Behavior	At Interface
Quantity	Functional Behavior	Value	Derivative wrt $ζ$	Derivative wrt $r$
Specific Entropy	$s (ζ) = s_{c} + H (ζ) \cdot (s_{e} - s_{c})$	$s_{i} \equiv s (0) = \frac{1}{2} (s_{c} + s_{e})$	$\frac{d s (ζ)}{d ζ} \|_{i} = (s_{e} - s_{c})$	$\frac{d s}{d r} \|_{i} = (s_{e} - s_{c}) / r_{i}$
Mean Molecular Weight	$μ (ζ) = μ_{c} + H (ζ) \cdot (μ_{e} - μ_{c})$	$μ_{i} \equiv μ (0) = \frac{1}{2} (μ_{c} + μ_{e})$	$\frac{d μ (ζ)}{d ζ} \|_{i} = (μ_{e} - μ_{c})$	$\frac{d μ}{d r} \|_{i} = (μ_{e} - μ_{c}) / r_{i}$
Ratio of Specific Heats	$γ (ζ) = γ_{c} + H (ζ) \cdot (γ_{e} - γ_{c})$	$γ_{i} \equiv γ (0) = \frac{1}{2} (γ_{c} + γ_{e})$	$\frac{d γ (ζ)}{d ζ} \|_{i} = (γ_{e} - γ_{c})$	$\frac{d γ}{d r} \|_{i} = (γ_{e} - γ_{c}) / r_{i}$

The step-function that arises in a proper description of the density distribution must be handled with a bit more care. Throughout the core,

$ρ_{c o r e}^{*}$

$=$

$(1 + \frac{ξ^{2}}{3})^{- 5 / 2},$

and,

$r^{*}$

$=$

$(\frac{3}{2 π})^{1 / 2} ξ;$

and throughout the envelope,

$ρ_{e n v}^{*}$

$=$

$(\frac{μ_{e}}{μ_{c}}) θ_{i}^{5} [\frac{η_{i}}{\sin (η_{i} - B)}] [\frac{\sin (η - B)}{η}],$

and,

$r^{*}$

$=$

$(\frac{μ_{e}}{μ_{c}})^{- 1} θ_{i}^{- 2} (2 π)^{- 1 / 2} η .$

The complete functional expression for the normalized mass density can therefore be written as,

$ρ^{*} (ζ)$	$=$	$ρ_{c o r e}^{} (ζ) + H (ζ) \cdot [ρ_{e n v}^{} (ζ) - ρ_{c o r e}^{*} (ζ)] .$
$\Rightarrow \frac{d}{d r^{}} [ρ^{} (ζ)]$	$=$	$\frac{d ρ_{c o r e}^{}}{d r^{}} + [ρ_{e n v}^{} (ζ) - ρ_{c o r e}^{} (ζ)] \frac{1}{r_{i}} \frac{d H (ζ)}{d ζ} + H (ζ) \cdot [\frac{d ρ_{e n v}^{}}{d r^{}} - \frac{d ρ_{c o r e}^{}}{d r^{}}] .$

Sanity check:

$ζ < 0 :$

$\frac{d}{d r^{*}} [ρ^{*} (ζ)]$

$=$

$\frac{d ρ_{c o r e}^{*}}{d r^{*}} + [ρ_{e n v}^{*} (ζ) - ρ_{c o r e}^{*} (ζ)] \frac{1}{r_{i}} {\frac{d H (ζ)}{d ζ}}^{0} + {H (ζ)}^{0} \cdot [\frac{d ρ_{e n v}^{*}}{d r^{*}} - \frac{d ρ_{c o r e}^{*}}{d r^{*}}] = \frac{d ρ_{c o r e}^{*}}{d r^{*}} .$
$ζ > 0 :$

$\frac{d}{d r^{*}} [ρ^{*} (ζ)]$

$=$

$\frac{d ρ_{c o r e}^{*}}{d r^{*}} + [ρ_{e n v}^{*} (ζ) - ρ_{c o r e}^{*} (ζ)] \frac{1}{r_{i}} {\frac{d H (ζ)}{d ζ}}^{0} + {H (ζ)}^{1} \cdot [\frac{d ρ_{e n v}^{*}}{d r^{*}} - \frac{d ρ_{c o r e}^{*}}{d r^{*}}] = \frac{d ρ_{e n v}^{*}}{d r^{*}} .$

ζ = 0 :

$\frac{d}{d r^{}} [ρ^{} (ζ)]$	$=$	$[\frac{d ρ_{c o r e}^{}}{d r^{}}]_{i} + [ρ_{e n v}^{} (ζ) - ρ_{c o r e}^{} (ζ)]_{i} \frac{1}{r_{i}} {\frac{d H (ζ)}{d ζ}}^{1} + {H (ζ)}^{1 / 2} \cdot [\frac{d ρ_{e n v}^{}}{d r^{}} - \frac{d ρ_{c o r e}^{}}{d r^{}}]_{i}$
	$=$	$\frac{1}{2} [\frac{d ρ_{e n v}^{}}{d r^{}} + \frac{d ρ_{c o r e}^{}}{d r^{}}]_{i} + \frac{1}{r_{i}} [ρ_{e n v}^{} (ζ) - ρ_{c o r e}^{} (ζ)]_{i} .$

Now Take Radial Derivative of Pressure

Solving for $P$ in the expression for specific entropy, we have,

$\ln [\frac{P^{}}{(ρ^{})^{γ}}]$	$=$	$\frac{μ (γ - 1) s}{ℜ}$
$\Rightarrow P^{*}$	$=$	$(ρ^{*})^{γ} \cdot \exp [\frac{μ (γ - 1) s}{ℜ}] .$

Hence,

$\frac{d P^{}}{d r^{}}$	$=$	$γ (ρ^{})^{γ - 1} {\exp [\frac{μ (γ - 1) s}{ℜ}]} \frac{d ρ^{}}{d r^{}} + (ρ^{})^{γ} {\exp [\frac{μ (γ - 1) s}{ℜ}]} \frac{d}{d r^{*}} [\frac{μ (γ - 1) s}{ℜ}]$
$\Rightarrow \frac{1}{P^{}} \cdot \frac{d P^{}}{d r^{*}}$	$=$	$\frac{γ}{ρ^{}} \frac{d ρ^{}}{d r^{}} + \frac{d}{d r^{}} [\frac{μ (γ - 1) s}{ℜ}] .$

We will need to recognize that, unless we are sitting exactly at the interface — that is, unless $ζ = 0$ precisely —

$\frac{d}{d r^{*}} [\frac{μ (γ - 1) s}{ℜ}]$

$=$

$0 .$

Hence, for two of the separate physical regimes …

$ζ < 0 :$

$\frac{d P^{*}}{d r^{*}}$

$=$

$γ (ρ^{*})^{γ - 1} {\exp [\frac{μ (γ - 1) s}{ℜ}]} \frac{d ρ^{*}}{d r^{*}}$

$\Rightarrow \frac{1}{P_{c o r e}^{*}} \cdot \frac{d P_{c o r e}^{*}}{d r^{*}}$

$=$

$\frac{γ_{c}}{ρ_{c o r e}^{*}} \cdot \frac{d ρ_{c o r e}^{*}}{d r^{*}}$
$ζ > 0 :$

$\frac{1}{P_{e n v}^{*}} \cdot \frac{d P_{e n v}^{*}}{d r^{*}}$

$=$

$\frac{γ_{e}}{ρ_{e n v}^{*}} \cdot \frac{d ρ_{e n v}^{*}}{d r^{*}}$

However, at the interface where $ζ = 0$ precisely, we find,

$\frac{ℤ_{0}}{r_{i}} \equiv {\frac{d}{d r^{*}} [\frac{μ (γ - 1) s}{ℜ}]}_{ζ = 0}$	$=$	$\frac{1}{ℜ} {(γ - 1) s \frac{d μ}{d r^{}} + μ s \frac{d γ}{d r^{}} + μ (γ - 1) \frac{d s}{d r^{*}}}_{ζ = 0}$
	$=$	$\frac{1}{ℜ} {(γ - 1) s \frac{d μ}{d r^{}} + μ s \frac{d γ}{d r^{}} + μ (γ - 1) \frac{d s}{d r^{*}}}_{ζ = 0}$
	$=$	$\frac{1}{ℜ} [\frac{1}{2} (μ_{c} + μ_{e})] [\frac{1}{2} (γ_{c} + γ_{e}) - 1] [\frac{1}{2} (s_{c} + s_{e})] {[\frac{2}{(μ_{c} + μ_{e})}] \frac{d μ}{d r^{}} + [\frac{2}{(γ_{c} + γ_{e}) - 1}] \frac{d γ}{d r^{}} + [\frac{2}{(s_{c} + s_{e})}] \frac{d s}{d r^{*}}}_{ζ = 0}$
	$=$	$\frac{1}{ℜ} [\frac{1}{2} (μ_{c} + μ_{e})] [\frac{1}{2} (γ_{c} + γ_{e}) - 1] [\frac{1}{2} (s_{c} + s_{e})] {\frac{2 (μ_{e} - μ_{c})}{(μ_{c} + μ_{e})} + \frac{2 (γ_{e} - γ_{c})}{(γ_{c} + γ_{e}) - 1} + \frac{2 (s_{e} - s_{c})}{(s_{c} + s_{e})}} \frac{1}{r_{i}^{*}}$
	$=$	$\frac{1}{2^{2} ℜ} {(μ_{e} - μ_{c}) [(γ_{c} + γ_{e}) - 1] (s_{c} + s_{e}) + (γ_{e} - γ_{c}) (μ_{c} + μ_{e}) (s_{c} + s_{e}) + (s_{e} - s_{c}) (μ_{c} + μ_{e}) [(γ_{c} + γ_{e}) - 1]} \frac{1}{r_{i}^{*}} .$

At the interface, then, we have,

$[\frac{1}{P^{}} \cdot \frac{d P^{}}{d r^{*}}]_{i}$	$=$	${\frac{γ}{ρ^{}} \frac{d ρ^{}}{d r^{}} + \frac{d}{d r^{}} [\frac{μ (γ - 1) s}{ℜ}]}_{ζ = 0}$
	$=$	$\frac{ℤ_{0}}{r_{i}} + {\frac{γ}{ρ^{}}}_{ζ = 0} \cdot {\frac{1}{2} [\frac{d ρ_{e n v}^{}}{d r^{}} + \frac{d ρ_{c o r e}^{}}{d r^{}}]_{i} + \frac{1}{r_{i}} [ρ_{e n v}^{} (ζ) - ρ_{c o r e}^{*} (ζ)]_{i}} .$

Finally, we see that,

${\frac{γ}{ρ^{*}}}_{ζ = 0}$	$=$	$\frac{1}{2} (γ_{c} + γ_{e}) {ρ_{c o r e}^{} (ζ) + H (ζ) \cdot [ρ_{e n v}^{} (ζ) - ρ_{c o r e}^{*} (ζ)]}_{ζ = 0}^{- 1}$
	$=$	$\frac{1}{2} (γ_{c} + γ_{e}) {\frac{1}{2} [ρ_{c o r e}^{} (ζ) + ρ_{e n v}^{} (ζ)]}_{ζ = 0}^{- 1}$
	$=$	$(γ_{c} + γ_{e}) [ρ_{c o r e}^{} (ζ) + ρ_{e n v}^{} (ζ)]_{i}^{- 1},$

so, at the interface,

$[\frac{1}{P^{*}} \cdot \frac{d P^{*}}{d r^{*}}]_{i}$

$=$

$\frac{ℤ_{0}}{r_{i}} + {\frac{1}{2} [\frac{d ρ_{e n v}^{*}}{d r^{*}} + \frac{d ρ_{c o r e}^{*}}{d r^{*}}]_{i} + \frac{1}{r_{i}} [ρ_{e n v}^{*} (ζ) - ρ_{c o r e}^{*} (ζ)]_{i}} (γ_{c} + γ_{e}) [ρ_{c o r e}^{*} (ζ) + ρ_{e n v}^{*} (ζ)]_{i}^{- 1} .$

Try Again

Additional studies of radial oscillations in models that lie along the "51 Renormalized" sequences can be found here.

Example BiPolytrope Sequence 0.3100

For the case of $(n_{c}, n_{e}) = (5, 1)$ and $μ_{e} / μ_{c} = 0.3100$ , we consider here the examination of models with three relatively significant values of the core/envelope interface:

$(ξ_{i}, \bar{ρ} / ρ_{c}, q, ν) \approx (2.06061, 1.1931 E + 02, 0.16296, 0.13754)$ : Approximate location along the sequence of the model with the maximum fractional core radius.
$(ξ_{i}, \bar{ρ} / ρ_{c}, q, ν) \approx (2.69697, 3.0676 E + 02, 0.15819, 0.19161)$ : Approximate location along the sequence of the onset of fundamental-mode instability.
$(ξ_{i}, \bar{ρ} / ρ_{c}, q, ν) \approx (9.0149598, 1.1664 E + 06, 0.075502255, 0.337217006)$ : Exact location along the sequence of the model with the maximum fractional core mass.

$- \frac{d \ln x}{d \ln η} \|_{s u r f}$	=	$1 + \frac{{σ_{c}^{2}}^{0}}{12} [\frac{η^{3}}{(η \cos η - \sin η)}]_{η = π} = 1$
$\Rightarrow \frac{1}{3} \cdot \frac{d x_{P}}{d η} \|_{s u r f}$	=	$- \frac{x_{P}}{3 η} \|_{i}$
	=	$- \frac{1}{η_{i}^{3}} [1 - η_{i} \cot η_{i}] = \frac{\cot η_{i}}{η_{i}^{2}} - \frac{1}{η_{i}^{3}} .$

@@ Line 213: / Line 213: @@
 </table>
+<span id="NewNormalization">&nbsp;</span>
 <table border="1" align="center" width="80%" cellpadding="5"><tr><td align="left">
@@ Line 251: / Line 252: @@
 </td></tr></table>
-After applying this new normalization, we have throughout the core,
+<span id="CoreParameters">After applying this new normalization, we have throughout the core,</span>
 <table border="0" align="center" cellpadding="5">
@@ Line 459: / Line 460: @@
 </table>
 </div>
-Adopting the new normalization then gives,
+<span id="EnvelopeParameters">Adopting the new normalization then gives,</span>
 <div align="center">
@@ Line 596: / Line 596: @@
 </table>
+<span id="Sequences">&nbsp;</span>
 <table border="1" align="center" cellpadding="10">
 <tr>
@@ Line 658: / Line 658: @@
 <tr>
    <td align="center" colspan="6"><b>Core</b></td>
-   <td align="center" rowspan="13">[[File:K-BK74eigenfunction.png|350px|B-KB74 Eigenfunction]]</td>
+   <td align="center" rowspan="13">
+[[File:DataFileButton02.png|right|60px|file = Dropbox/WorkFolder/Wiki edits/BiPolytrope/qAndNuMaxAug21.xlsx --- worksheet = B1renorm]]<br />
+[[File:K-BK74eigenfunction.png|350px|B-KB74 Eigenfunction]]
+</td>
 </tr>
 <tr>
@@ Line 1,340: / Line 1,343: @@
 </table>
-==Numerical Integration Through Envelope==
+===2<sup>nd</sup> Trial===
-In an effort to numerically determine the eigenfunction of the envelope, we will follow the procedure described in an [[SSC/Stability/Polytropes#Numerical_Integration_from_the_Center,_Outward|accompanying stability analysis of pressure-truncated polytropes]] to integrate the <math>n = 1</math> envelope from the core/envelope interface to the surface.  In a [[SSC/Stability/n1PolytropeLAWE#Radial_Oscillations_of_n_=_1_Polytropic_Spheres|closely related chapter titled, ''Radial Oscillations of n = 1 Polytropic Spheres'']], we have tried to find analytic expressions for the eigenvector of marginally unstable configurations.
+The relevant LAWE for the envelope is,
+<table border=0 cellpadding=2 align="center">
-===Setup===
+<tr>
+  <td align="right"><math>\biggl[ \frac{A\sin(\eta-B)}{\eta}\biggr]\frac{d^2x}{d\eta^2} </math></td>
-====Continuous Form  of LAWE====
+  <td align="center"><math>=</math></td>
-We begin by writing our generic version of the polytropic LAWE,
+  <td align="left">
-<div align="center">
+<math>
-{{ Math/EQ_RadialPulsation02 }}
+- \frac{2A}{\eta}\biggl\{ \sin(\eta - B) + \eta\cos(\eta - B) \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
-</div>
++ \frac{2A}{\eta} \biggl\{ \sin(\eta - B) - \eta\cos(\eta - B) \biggr\}  \frac{x}{\eta^2}
+- 2 \biggl( \frac{\sigma_c^2}{12} \biggr) x
-then focus on the <math>n=1</math> case &#8212; setting <math>\gamma_g = 1 + 1/n = 2</math> and <math>\alpha = +1</math> &#8212; the relevant LAWE becomes,
+</math>
-<table border=0 cellpadding=2 align="center">
+</td>
+</tr>
 <tr>
-   <td align="right"><math>0</math></td>
+   <td align="right"><math>\Rightarrow ~~~ \frac{1}{3\beta} \cdot \frac{d^2x}{d\eta^2} </math></td>
    <td align="center"><math>=</math></td>
    <td align="left">
-<math>\frac{d^2x}{d\eta^2} + \biggl\{ 4 - 2 Q \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
+<math>
-+ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^2}{\phi}
+- \frac{2}{\eta}\biggl\{ 1 + \eta\cot(\eta - B) \biggr\} \biggl[ \frac{1}{3\beta } \cdot \frac{dx}{d\eta} \biggr]
-- Q\biggr\}  \frac{x}{\eta^2} \, ,</math>
++ 2 \biggl\{ 1 - \eta\cot(\eta - B) \biggr\}  \frac{x}{3\beta\eta^2}
+- 2 \biggl( \frac{\sigma_c^2}{12} \biggr) \biggl[ \frac{\eta}{3 \beta A\sin(\eta-B)}\biggr] x
+\, .
+</math>
 </td>
 </tr>
 </table>
+Here, we will ''guess'' a displacement function, <math>x_\mathrm{env}</math>, of the form,
-where, in the broadest context,
 <table border="0" cellpadding="5" align="center">
@@ Line 1,372: / Line 1,379: @@
 <tr>
    <td align="right">
-<math>\phi(\eta)</math>
+<math>\frac{x_\mathrm{env}}{3\beta}</math>
    </td>
    <td align="center">
@@ Line 1,379: / Line 1,386: @@
    <td align="left">
 <math>
-A \biggl[ \frac{\sin(\eta-B)}{\eta}\biggr] \, ,
+\frac{1}{\eta^2 } \biggl[1 - \eta\cot(\eta - B_x) \biggr]
+=
+\frac{1}{\eta^2 }  - \frac{\cos(\eta - B_x)}{\eta\sin(\eta - B_x)}
+\, ,
 </math>
    </td>
 </tr>
+</table>
+where we will assume, quite generally, that <math>B_x \ne B</math>.  The first and second derivatives of <math>x_\mathrm{env}</math> are,
+<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>-\frac{d\phi}{d\eta}</math>
+<math>\frac{1}{3\beta} \biggl[ \frac{dx_\mathrm{env}}{d\eta} \biggr]</math>
    </td>
    <td align="center">
@@ Line 1,393: / Line 1,407: @@
    <td align="left">
 <math>
-\frac{A}{\eta^2} \biggl[\sin(\eta-B) - \eta\cos(\eta - B) \biggr] \, ,
+-\frac{2}{\eta^3 }
++
+\frac{\cos(\eta - B_x)}{\eta^2\sin(\eta - B_x)}
++
+\frac{\sin(\eta - B_x)}{\eta\sin(\eta - B_x)}
++
+\frac{\cos^2(\eta - B_x)}{\eta\sin^2(\eta - B_x)}
 </math>
    </td>
@@ Line 1,400: / Line 1,420: @@
 <tr>
    <td align="right">
-<math>\Rightarrow ~~~ Q(\eta) \equiv - \frac{d\ln\phi}{d\ln\eta}</math>
+&nbsp;
    </td>
    <td align="center">
@@ Line 1,407: / Line 1,427: @@
    <td align="left">
 <math>
-\frac{A}{\eta^2} \biggl[\sin(\eta-B) - \eta\cos(\eta - B) \biggr] \cdot \frac{\eta^2}{A\sin(\eta-B)}
+-\frac{2}{\eta^3 }
++
+\frac{1}{\eta}
++
+\frac{\cos(\eta - B_x)}{\eta^2\sin(\eta - B_x)}
++
+\frac{\cos^2(\eta - B_x)}{\eta\sin^2(\eta - B_x)}
+\, ;
 </math>
    </td>
@@ Line 1,414: / Line 1,441: @@
 <tr>
    <td align="right">
-&nbsp;
+<math>\frac{1}{3\beta} \biggl[ \frac{d^2x_\mathrm{env}}{d\eta^2} \biggr]</math>
    </td>
    <td align="center">
@@ Line 1,421: / Line 1,448: @@
    <td align="left">
 <math>
-\biggl[1 - \eta\cot(\eta - B) \biggr] \, .
+\frac{6}{\eta^4} - \frac{1}{\eta^2}
+- \frac{2\cos(\eta-B_x)}{\eta^3\sin(\eta-B_x)}
++ \frac{1}{\eta^2}\biggl[
+- \frac{\sin(\eta - B_x)}{\sin(\eta - B_x)}
+-
+\frac{\cos^2(\eta - B_x)}{\sin^2(\eta - B_x)}
+\biggr]
+-
+\frac{\cos^2(\eta - B_x)}{\eta^2\sin^2(\eta - B_x)}
++ \frac{1}{\eta} \biggl[
+-
+\frac{2\cos(\eta - B_x)}{\sin(\eta - B_x)}
+-
+\frac{2\cos^3(\eta - B_x)}{\sin^3(\eta - B_x)}
+\biggr]
 </math>
    </td>
 </tr>
-</table>
-For the <math>n=1</math> LAWE we therefore have,
-<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right"><math>0</math></td>
+   <td align="right">
-   <td align="center"><math>=</math></td>
+&nbsp;
+  </td>
+   <td align="center">
+<math>=</math>
+  </td>
    <td align="left">
-<math>\frac{d^2x}{d\eta^2} + \biggl\{ 4 - 2 \biggl[1 - \eta\cot(\eta - B) \biggr] \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
+<math>
-+ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{A\sin(\eta-B)}
+\frac{6}{\eta^4} - \frac{1}{\eta^2}
-- \biggl[1 - \eta\cot(\eta - B) \biggr]\biggr\}  \frac{x}{\eta^2}</math>
+- \frac{2\cos(\eta-B_x)}{\eta^3\sin(\eta-B_x)}
-</td>
+- \frac{1}{\eta^2}\biggl[
++
+\frac{\cos^2(\eta - B_x)}{\sin^2(\eta - B_x)}
+\biggr]
+-
+\frac{\cos^2(\eta - B_x)}{\eta^2\sin^2(\eta - B_x)}
+- \frac{1}{\eta}\biggl[
+\frac{2\cos(\eta - B_x)}{\sin(\eta - B_x)}
++
+\frac{2\cos^3(\eta - B_x)}{\sin^3(\eta - B_x)}
+\biggr]
+</math>
+  </td>
 </tr>
 <tr>
-   <td align="right">&nbsp;</td>
+   <td align="right">
-   <td align="center"><math>=</math></td>
+&nbsp;
-   <td align="left">
+   </td>
-<math>\frac{d^2x}{d\eta^2} + 2\biggl\{ 1 + \eta\cot(\eta - B) \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
+   <td align="center">
-+ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{A\sin(\eta-B)}
+<math>=</math>
-- 1 + \eta\cot(\eta - B) \biggr\}  \frac{x}{\eta^2} \, .</math>
+   </td>
-</td>
-</tr>
-</table>
-Multiplying through by <math>\phi</math>, we can write,
-<table border=0 cellpadding=2 align="center">
-<tr>
-  <td align="right"><math>\biggl[ \frac{A\sin(\eta-B)}{\eta}\biggr]\frac{d^2x}{d\eta^2} </math></td>
-   <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-- \frac{2A}{\eta}\biggl\{ \sin(\eta - B) + \eta\cos(\eta - B) \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
+\frac{6}{\eta^4} - \frac{2}{\eta^2}
-+ \frac{2A}{\eta} \biggl\{ \sin(\eta - B) - \eta\cos(\eta - B) \biggr\}  \frac{x}{\eta^2}
+- \frac{2\cos(\eta-B_x)}{\eta^3\sin(\eta-B_x)}
-- 2 \biggl( \frac{\sigma_c^2}{12} \biggr) x \, .
+- \frac{2}{\eta^2}\biggl[
+\frac{\cos^2(\eta - B_x)}{\sin^2(\eta - B_x)}
+\biggr]
+- \frac{2}{\eta}\biggl[
+\frac{\cos(\eta - B_x)}{\sin(\eta - B_x)}
++
+\frac{\cos^3(\eta - B_x)}{\sin^3(\eta - B_x)}
+\biggr]
 </math>
-</td>
+  </td>
 </tr>
-</table>
-====Discrete Form  of LAWE====
-In order to integrate this 2<sup>nd</sup>-order ODE numerically, we will build from the [[SSC/Stability/Polytropes#Numerical_Integration_from_the_Center,_Outward|more general expression for polytropes used in our separate development of a finite-difference scheme]], namely,
-<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>\theta_i {x_i''}</math>
+&nbsp;
    </td>
    <td align="center">
@@ Line 1,478: / Line 1,525: @@
    </td>
    <td align="left">
-<math>- \biggl[4\theta_i - (n+1)\xi_i (- \theta^')_i\biggr] \frac{x_i'}{\xi_i}
+<math>
-- (n+1)\biggl[ \frac{\sigma_c^2}{6\gamma_g}  -
+\frac{6}{\eta^4} - \frac{2}{\eta^2}\biggl[1 + \cot^2(\eta - B_x) \biggr]
-\frac{\alpha}{\xi_i } (- \theta^')_i\biggr]  x_i \, .</math>
+- \frac{2\cot(\eta-B_x)}{\eta^3}
+- \frac{2}{\eta}\biggl[
+\cot(\eta - B_x)
++
+\cot^3(\eta - B_x)
+\biggr]\, .
+</math>
    </td>
 </tr>
 </table>
-Making the notation substitutions, <math>(\xi, \theta) \rightarrow (\eta, \phi)</math>, we have instead,
+These match the expressions for <math>dx_P/d\eta</math> and <math>d^2x_P/d\eta^2</math> that we separately derived in a [[Appendix/Ramblings/BiPolytrope51AnalyticStability#Attempt_4B|subsection labeled ''Attempt_4B'' of an accompanying discussion labeled]].  Plugging these three relations into the LAWE, then multiplying through by <math>\eta^4</math>, gives,
-<table border="0" cellpadding="5" align="center">
+<table border=0 cellpadding=2 align="center">
 <tr>
    <td align="right">
-<math>\phi_i {x_i''}</math>
+<math>
-  </td>
+\frac{6}{\eta^4} - \frac{2}{\eta^2}\biggl[1 + \cot^2(\eta - B_x) \biggr]
-   <td align="center">
+- \frac{2\cot(\eta-B_x)}{\eta^3}
-<math>=</math>
+- \frac{2}{\eta}\biggl[
-  </td>
+\cot(\eta - B_x)
++
+\cot^3(\eta - B_x)
+\biggr]
+</math>
+</td>
+   <td align="center"><math>=</math></td>
    <td align="left">
-<math>- \biggl[4\phi_i - (n+1)\eta_i (- \phi^')_i\biggr] \frac{x_i'}{\eta_i}
+<math>
-- (n+1)\biggl[ \frac{\sigma_c^2}{6\gamma_g}  -
+- \frac{2}{\eta}\biggl\{ 1 + \eta\cot(\eta - B) \biggr\} \biggl[ -\frac{2}{\eta^3 }
-\frac{\alpha}{\eta_i } (- \phi^')_i\biggr]  x_i \, .</math>
++
-  </td>
+\frac{1}{\eta}
++
+\frac{\cot(\eta - B_x)}{\eta^2}
++
+\frac{\cot^2(\eta - B_x)}{\eta}
+ \biggr]
+</math>
+</td>
 </tr>
-</table>
-Now, adopting the finite-difference expressions,
-<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>x_i'</math>
+&nbsp;
-  </td>
-  <td align="center">
-<math>\approx</math>
    </td>
+  <td align="center">&nbsp;</td>
    <td align="left">
-<math>\frac{x_+ - x_-}{2 \Delta_\eta} \, ,</math>&nbsp; &nbsp; and,
+<math>
-  </td>
++ \biggl\{
+\biggl[ 1 - \eta\cot(\eta - B) \biggr]  \frac{1}{\eta^2}
+- 2 \biggl( \frac{\sigma_c^2}{12} \biggr) \biggl[ \frac{\eta}{ A\sin(\eta-B)}\biggr]
+\biggr\} \biggl[ \frac{1}{\eta^2 }  - \frac{\cot(\eta - B_x)}{\eta}\biggr]
+</math>
+</td>
 </tr>
 <tr>
    <td align="right">
-<math>
+<math>\Rightarrow ~~~
-x_i''
+- 2\eta^2 \biggl[1 + \cot^2(\eta - B_x) \biggr]
+- 2\eta \cot(\eta-B_x)
+- 2\eta^3 \biggl[
+\cot(\eta - B_x)
++
+\cot^3(\eta - B_x)
+\biggr]
 </math>
-  </td>
+</td>
-   <td align="center">
+   <td align="center"><math>=</math></td>
-<math>\approx</math>
+   <td align="left">
-  </td>
+<math>
-   <td align="left">
+- 2\biggl\{ 1 + \eta\cot(\eta - B) \biggr\} \biggl[ -2
-<math>\frac{x_+ - 2x_i + x_-}{\Delta_\eta^2} \, ,</math>
++
-  </td>
+\eta^2
++
+\eta\cot(\eta - B_x)
++
+\eta^2 \cot^2(\eta - B_x)
+ \biggr]
+</math>
+</td>
 </tr>
-</table>
-</div>
-<span id="DiscreteLAWE">the discrete form of the LAWE becomes,</span>
-<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>x_+ \overbrace{\biggl[2\phi_i +\frac{4\Delta_\eta \phi_i}{\eta_i} - \Delta_\eta (n+1)(- \phi^')_i\biggr]}^{\mathrm{TERM1}} </math>
+&nbsp;
-  </td>
-  <td align="center">
-<math>=</math>
    </td>
+  <td align="center">&nbsp;</td>
    <td align="left">
 <math>
-x_- \overbrace{\biggl[\frac{4\Delta_\eta \phi_i}{\eta_i} - \Delta_\eta (n+1)(- \phi^')_i - 2\phi_i\biggr]}^{\mathrm{TERM2}}
++ \biggl\{
-+  x_i \overbrace{\biggl\{4\phi_i - \frac{\Delta_\eta^2(n+1)}{3}\biggl[ \frac{\sigma_c^2}{\gamma_g}  -
+\biggl[ 1 - \eta\cot(\eta - B) \biggr]
-\alpha \biggl(- \frac{3\phi^'}{\eta}\biggr)_i\biggr]  \biggr\}}^{\mathrm{TERM3}} \, .</math>
+- 2 \biggl( \frac{\sigma_c^2}{12} \biggr) \biggl[ \frac{\eta^3}{ A\sin(\eta-B)}\biggr]
-  </td>
+\biggr\} \biggl[ 1  - \eta \cot(\eta - B_x)\biggr]
+</math>
+</td>
 </tr>
 </table>
-When applied specifically to an <math>n=1</math>, polytropic configuration, we should insert the following specific expressions:
+<table border=0 cellpadding=2 align="center">
-<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>\gamma_g</math>
+<math>\Rightarrow ~~~
-  </td>
+\biggl( \frac{\sigma_c^2}{6} \biggr) \biggl[ \frac{\eta^3}{ A\sin(\eta-B)}\biggr]
-   <td align="center">
+\biggl[ 1  - \eta \cot(\eta - B_x)\biggr]
-<math>=</math>
+</math>
-  </td>
+</td>
+   <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-+ \frac{1}{n} = 2
+\biggl[ 1 + \eta\cot(\eta - B) \biggr] \biggl[ 4
-\, ,</math>
+-
-  </td>
+\eta^2
+-
+\eta\cot(\eta - B_x)
+-
+\eta^2 \cot^2(\eta - B_x)
+ \biggr]
+</math>
+</td>
 </tr>
 <tr>
    <td align="right">
-<math>\alpha</math>
+&nbsp;
-  </td>
-  <td align="center">
-<math>=</math>
    </td>
+  <td align="center">&nbsp;</td>
    <td align="left">
 <math>
-- \frac{4}{\gamma_g} = +1
++
-\, ,</math>
+\biggl[ 1 - \eta\cot(\eta - B) \biggr]
-  </td>
+\biggl[ 1  - \eta \cot(\eta - B_x)\biggr]
+-6 + 2\eta^2 \biggl[1 + \cot^2(\eta - B_x) \biggr]
++ 2\eta \cot(\eta-B_x)
++ 2\eta^3 \biggl[
+\cot(\eta - B_x)
++
+\cot^3(\eta - B_x)
+\biggr]
+</math>
+</td>
 </tr>
 <tr>
    <td align="right">
-<math>\phi_i</math>
+&nbsp;
-  </td>
-  <td align="center">
-<math>=</math>
    </td>
+  <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-A \biggl[ \frac{\sin(\eta_i-B)}{\eta_i}\biggr] \, ,
+\biggl[ 4 - 2\eta^2 - 2\eta\cot(\eta - B_x) - 2\eta^2 \cot^2(\eta - B_x)\biggr]
++
+\eta\cot(\eta - B)
+\biggl[ 4 - 2\eta^2 - 2\eta\cot(\eta - B_x) - 2\eta^2 \cot^2(\eta - B_x)\biggr]
 </math>
-  </td>
+</td>
 </tr>
 <tr>
    <td align="right">
-<math>(-\phi')_i</math>
+&nbsp;
-  </td>
-  <td align="center">
-<math>=</math>
    </td>
+  <td align="center">&nbsp;</td>
    <td align="left">
 <math>
-\frac{A}{\eta_i^2} \biggl[\sin(\eta_i-B) - \eta_i \cos(\eta_i - B) \biggr] \, .
++
+\biggl[ 2 - 2\eta\cot(\eta - B) - 2\eta \cot(\eta - B_x) + 2\eta^2 \cot(\eta - B)\cot(\eta - B_x)\biggr]
+-6 + 2\eta^2 + 2\eta^2 \cot^2(\eta - B_x)
++ 2\eta \cot(\eta-B_x)
++ 2\eta^3 \cot(\eta - B_x)
++ 2\eta^3 \cot^3(\eta - B_x)
 </math>
-  </td>
+</td>
 </tr>
-</table>
-===Pressure-Truncated n = 1 Polytrope===
-In the case of an isolated, pressure-truncated <math>n=1</math> polytrope, we must set <math>B = 0</math>; in addition, it is customary to set <math>A = 1</math>.  The relevant LAWE is, then,
-<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right"><math>0</math></td>
+   <td align="right">
+&nbsp;
+  </td>
    <td align="center"><math>=</math></td>
    <td align="left">
-<math>\frac{d^2x}{d\eta^2} + 2\biggl\{ 1 + \eta\cot(\eta) \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
+<math>
-+ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{\sin(\eta)}
+- 2\eta\cot(\eta - B_x) - 2\eta^2 \cot^2(\eta - B_x)
-- 1 + \eta\cot(\eta) \biggr\}  \frac{x}{\eta^2} \, .</math>
++
+\eta\cot(\eta - B) - 2\eta^3\cot(\eta - B) - 2\eta^2 \cot(\eta - B)\cot(\eta - B_x) - 2\eta^3\cot(\eta - B) \cot^2(\eta - B_x)
+</math>
 </td>
 </tr>
-</table>
-====Review of Trial Analytic Eigenfunction====
-This is the same 2<sup>nd</sup>-order ODE that we derived in a [[SSC/Stability/n1PolytropeLAWE#WorkInProgress|separate discussion]]; there it was accompanied by the [[SSC/Stability/Polytropes#Boundary_Conditions|surface boundary condition]],
-<table border="0" align="center" cellpadding="5">
 <tr>
    <td align="right">
-<math>- \frac{d\ln x}{d\ln \xi} \biggr|_\mathrm{surf}</math>
+&nbsp;
    </td>
-   <td align="center">=</td>
+   <td align="center">&nbsp;</td>
    <td align="left">
 <math>
-\biggl( \frac{3-n}{n+1}\biggr) + \frac{n\sigma_c^2}{6(n+1)}
+- 2\eta\cot(\eta - B) - 2\eta \cot(\eta - B_x) + 2\eta^2 \cot(\eta - B)\cot(\eta - B_x)
-\biggl[ \frac{\xi}{\theta'}\biggr]_\mathrm{surf}
++ 2\eta^2 \cot^2(\eta - B_x)
++ 2\eta \cot(\eta-B_x)
++ 2\eta^3 \cot(\eta - B_x)
++ 2\eta^3 \cot^3(\eta - B_x)
 </math>
-  </td>
+</td>
 </tr>
 <tr>
    <td align="right">
-<math>\Rightarrow ~~~ - \frac{d\ln x}{d\ln \eta} \biggr|_\mathrm{surf}</math>
+&nbsp;
    </td>
-   <td align="center">=</td>
+   <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-+ \frac{\sigma_c^2}{12}
+- 2\eta^3 \biggl[\cot(\eta - B)  +\cot(\eta - B) \cot^2(\eta - B_x)
-\biggl[ \frac{\eta^3}{(\eta \cos\eta - \sin\eta)}\biggr]_{\eta=\pi}
+- \cot(\eta - B_x) - \cot^3(\eta - B_x) \biggr]
-=
++ 2\eta \biggl[\cot(\eta - B) - \cot(\eta - B_x) \biggr]
-- \frac{\pi^2 \sigma_c^2}{12} \, .
 </math>
-  </td>
+</td>
 </tr>
 </table>
-From, for example, a separate [[SSC/Stability/n1PolytropeLAWE#Succinct_Demonstration|succinct demonstration]], we appreciate that if the displacement function is assumed to be,
+Notice that if we set <math>B_x = B</math>, the RHS of this LAWE expression goes to zero.  This [thankfully] is as expected.
+==Numerical Integration Through Envelope==
-<table border="0" cellpadding="5" align="center">
+In an effort to numerically determine the eigenfunction of the envelope, we will follow the procedure described in an [[SSC/Stability/Polytropes#Numerical_Integration_from_the_Center,_Outward|accompanying stability analysis of pressure-truncated polytropes]] to integrate the <math>n = 1</math> envelope from the core/envelope interface to the surface.  In a [[SSC/Stability/n1PolytropeLAWE#Radial_Oscillations_of_n_=_1_Polytropic_Spheres|closely related chapter titled, ''Radial Oscillations of n = 1 Polytropic Spheres'']], we have tried to find analytic expressions for the eigenvector of marginally unstable configurations.
-<tr>
+===Setup===
-  <td align="right">
-<math>x_P</math>
-  </td>
-  <td align="center">
-<math>=</math>
-  </td>
-  <td align="left">
-<math>\frac{3}{\eta^2} \biggl[ 1 - \eta \cot\eta \biggr] </math>
-  </td>
-</tr>
-</table>
-<table border="1" align="center" cellpadding="5" width="80%"><tr><td align="left">
+====Continuous Form  of LAWE====
-&hellip; that is,
+We begin by writing our generic version of the polytropic LAWE,
+<div align="center">
+{{ Math/EQ_RadialPulsation02 }}
+</div>
-<table border="0" cellpadding="5" align="center">
+then focus on the <math>n=1</math> case &#8212; setting <math>\gamma_g = 1 + 1/n = 2</math> and <math>\alpha = +1</math> &#8212; the relevant LAWE becomes,
+<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>0</math></td>
-<math>x_P</math>
+   <td align="center"><math>=</math></td>
-  </td>
-   <td align="center">
-<math>=</math>
-  </td>
    <td align="left">
-<math>\frac{3}{\eta^2}  - \frac{3 \cos\eta}{\eta \sin\eta} \, , </math>
+<math>\frac{d^2x}{d\eta^2} + \biggl\{ 4 - 2 Q \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
-  </td>
++ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^2}{\phi}
+- Q\biggr\}  \frac{x}{\eta^2} \, ,</math>
+</td>
 </tr>
 </table>
-in which case,
+<table border="1" width="80%" cellpadding="8" align="center">
+<tr>
+  <td align="center" bgcolor="pink">
+{{ Chatterji51 }} &#8212; STEP 1
+  </td>
+</tr>
+<tr><td align="left">
+If we focus on the <math>n=1</math> case but leave <math>\gamma</math> (and, hence, <math>\alpha</math>) unspecified, the relevant LAWE becomes,
+<table border=0 cellpadding=2 align="center">
-<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math>0</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>\frac{d^2x}{d\eta^2} + \biggl\{ 4 - 2 Q \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
++ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{6\gamma} \biggr)  \frac{\eta^2}{\phi}
+- \alpha Q\biggr\}  \frac{x}{\eta^2} \, .</math>
+</td>
+</tr>
+</table>
+If, in addition, we make the notation substitutions,
+<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>Q</math></td>
-<math>\frac{dx_P}{d\eta}</math>
+  <td align="center"><math>~~~\rightarrow~~~</math></td>
-  </td>
+   <td align="left">
-   <td align="center">
+<math>\frac{\mu}{n+1} = \frac{\mu}{2}</math>
-<math>=</math>
    </td>
+<td align="center">&nbsp; &nbsp; &nbsp; and, &nbsp; &nbsp; &nbsp;</td>
+  <td align="right"><math>\frac{\sigma_c^2}{3\gamma}</math></td>
+  <td align="center"><math>~~~\rightarrow~~~</math></td>
    <td align="left">
-<math>
+<math>\omega^2_\mathrm{Chatterji} \, ,</math>
--\frac{6}{\eta^3} + 3\biggl[\frac{\cos\eta}{\eta^2\sin\eta} + \frac{1}{\eta} + \frac{\cos^2\eta}{\eta\sin^2\eta}\biggr]
-\, ,
-</math>
    </td>
 </tr>
 </table>
-and,
+the relevant LAWE becomes,
+<table border=0 cellpadding=2 align="center">
-<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right"><math>0</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>\frac{d^2x}{d\eta^2} + \biggl\{ 4 - \mu \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
++ \biggl\{ \biggl( \frac{\sigma_c^2}{3\gamma} \biggr)  \frac{\eta^2}{\phi}
+- \alpha \mu\biggr\}  \frac{x}{\eta^2} </math>
+</td>
 <tr>
-   <td align="right">
+   <td align="right">&nbsp;</td>
-<math>\frac{d^2x_P}{d\eta^2}</math>
+  <td align="center"><math>=</math></td>
-   </td>
+  <td align="left">
-   <td align="center">
+<math>\frac{d^2x}{d\eta^2} + \biggl[ \frac{4 - \mu}{\eta} \biggr] \frac{dx}{d\eta}
-<math>=</math>
++ \biggl[ \frac{\omega^2_\mathrm{Chatterji}}{\phi}
+- \frac{\alpha \mu}{\eta^2}\biggr]  x \, ,</math>
+</td>
+</tr>
+</tr>
+</table>
+which, apart from notation, is identical to equation (1) of {{ Chatterji51 }}.
+</td></tr>
+</table>
+Now, in the broadest context,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>\phi(\eta)</math>
+   </td>
+   <td align="center">
+<math>=</math>
    </td>
    <td align="left">
 <math>
-+\frac{18}{\eta^4}
+A \biggl[ \frac{\sin(\eta-B)}{\eta}\biggr] \, ,
-+
-\frac{d}{d\eta}\biggl[ \frac{\cos\eta}{\eta^2\sin\eta} \biggr]
-+ 3\frac{d}{d\eta}\biggl[ \frac{1}{\eta} \biggr]
-+ 3\frac{d}{d\eta}\biggl[ \frac{\cos^2\eta}{\eta\sin^2\eta} \biggr]
 </math>
    </td>
@@ Line 1,740: / Line 1,862: @@
 <tr>
    <td align="right">
-&nbsp;
+<math>-\frac{d\phi}{d\eta}</math>
    </td>
    <td align="center">
@@ Line 1,747: / Line 1,869: @@
    <td align="left">
 <math>
-+\frac{18}{\eta^4}
+\frac{A}{\eta^2} \biggl[\sin(\eta-B) - \eta\cos(\eta - B) \biggr] \, ,
--
-\biggl[ \frac{ 2\cos\eta}{\eta^3\sin\eta} + \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{\sin\eta}{\eta^2\sin\eta} \biggr]
-- \biggl[ \frac{3}{\eta^2} \biggr]
-- 3\biggl[ \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{2\cos^3\eta}{\eta\sin^3\eta} + \frac{2\cos\eta}{\eta\sin\eta} \biggr]
-\, .
 </math>
    </td>
 </tr>
-</table>
-Hence,
-<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right">LAWE</td>
+   <td align="right">
-   <td align="center"><math>=</math></td>
+<math>\Rightarrow ~~~ Q(\eta) \equiv - \frac{d\ln\phi}{d\ln\eta}</math>
-   <td align="left">
+  </td>
+   <td align="center">
+<math>=</math>
+  </td>
+   <td align="left">
 <math>
-\biggl\{ \frac{2}{\eta} + \frac{2\cos\eta}{\sin\eta} \biggr\}  \biggl\{
+\frac{A}{\eta^2} \biggl[\sin(\eta-B) - \eta\cos(\eta - B) \biggr] \cdot \frac{\eta^2}{A\sin(\eta-B)}
--\frac{6}{\eta^3} + \biggl[\frac{3\cos\eta}{\eta^2\sin\eta} + \frac{3}{\eta} + \frac{3\cos^2\eta}{\eta\sin^2\eta}\biggr]
-\biggr\}
-+ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{\sin(\eta)}
-- 1 + \frac{\eta\cos\eta}{\sin\eta} \biggr\} \biggl[ \frac{3}{\eta^4}  - \frac{3 \cos\eta}{\eta^3 \sin\eta} \biggr]
 </math>
-</td>
+  </td>
 </tr>
 <tr>
-   <td align="right">&nbsp;</td>
+   <td align="right">
-   <td align="center">&nbsp;</td>
+&nbsp;
+  </td>
+   <td align="center">
+<math>=</math>
+  </td>
    <td align="left">
 <math>
-+\frac{18}{\eta^4}
+\biggl[1 - \eta\cot(\eta - B) \biggr] \, .
--
-\biggl[ \frac{ 2\cos\eta}{\eta^3\sin\eta} + \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{\sin\eta}{\eta^2\sin\eta} \biggr]
-- \biggl[ \frac{3}{\eta^2} \biggr]
-- 3\biggl[ \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{2\cos^3\eta}{\eta\sin^3\eta} + \frac{2\cos\eta}{\eta\sin\eta} \biggr]
 </math>
-</td>
+  </td>
 </tr>
+</table>
+<table border="1" width="80%" cellpadding="8" align="center">
 <tr>
-   <td align="right">&nbsp;</td>
+   <td align="center" bgcolor="pink">
-   <td align="center"><math>=</math></td>
+{{ Chatterji51 }} &#8212; STEP 2
+  </td>
+</tr>
+<tr><td align="left">
+In the context of an isolated, <math>n=1</math> polytrope, the appropriate parameter values are, <math>A=1</math> and <math>B=0</math>, in which case,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>\phi(\eta)</math>
+  </td>
+   <td align="center">
+<math>=</math>
+  </td>
    <td align="left">
 <math>
-\biggl[ \frac{2}{\eta} + 2\cot\eta \biggr]  \biggl[
+\frac{\sin\eta}{\eta} \, ,
--\frac{6}{\eta^3} + \frac{3\cot\eta}{\eta^2} + \frac{3}{\eta} + \frac{3\cot^2\eta}{\eta}
-\biggr]
-+ \biggl\{ \biggl( \frac{\sigma_c^2}{6} \biggr)  \frac{\eta^3}{\sin\eta}
-\biggr\} \biggl[ \frac{3}{\eta^4}  - \frac{3 \cot\eta}{\eta^3 } \biggr]
-+ \biggl[- 2 + 2\eta\cot\eta \biggr] \biggl[ \frac{3}{\eta^4}  - \frac{3 \cot\eta}{\eta^3 } \biggr]
 </math>
-</td>
+  </td>
-</tr>
+<td align="center">&nbsp; &nbsp; &nbsp; and, &nbsp; &nbsp; &nbsp;</td>
+   <td align="right">
-<tr>
+<math>\mu = 2Q</math>
-   <td align="right">&nbsp;</td>
+  </td>
-   <td align="center">&nbsp;</td>
+   <td align="center">
+<math>=</math>
+  </td>
    <td align="left">
 <math>
-+\frac{18}{\eta^4}
+(1 - \eta\cot\eta ) \, ,
--
-\biggl[ \frac{ 6\cot\eta}{\eta^3} + \frac{3\cot^2\eta}{\eta^2} + \frac{3}{\eta^2} \biggr]
-- \biggl[ \frac{3}{\eta^2} \biggr]
-- \biggl[ \frac{3\cot^2\eta}{\eta^2} + \frac{6\cot^3\eta}{\eta} + \frac{6\cot\eta}{\eta} \biggr]
 </math>
-</td>
+  </td>
 </tr>
+</table>
+and the relevant LAWE becomes,
+<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right">&nbsp;</td>
+   <td align="right"><math>0</math></td>
    <td align="center"><math>=</math></td>
    <td align="left">
-<math>
+<math>\frac{d^2x}{d\eta^2} + \biggl[ \frac{4 + 2(\eta\cot\eta-1)}{\eta} \biggr] \frac{dx}{d\eta}
-\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
++ \biggl[ \frac{\eta ~\omega^2_\mathrm{Chatterji}}{\sin\eta}
-\biggl[ 1  - \eta \cot\eta \biggr]
++ \frac{2 \alpha (\eta\cot\eta-1)}{\eta^2}\biggr]  x </math>
-+
-\biggl[ -\frac{12}{\eta^4} + \frac{6}{\eta^2} \biggr]
-+
-\biggl[ 2\cot\eta \biggr]\biggl[ \frac{3}{\eta^3}  + \frac{3\cot\eta}{\eta^2} \biggr]
-+
-\biggl[ 2\cot\eta \biggr]  \biggl[
--\frac{6}{\eta^3} + \frac{3\cot\eta}{\eta^2} + \frac{3}{\eta} + \frac{3\cot^2\eta}{\eta}
-\biggr]
-</math>
 </td>
 </tr>
@@ Line 1,838: / Line 1,954: @@
 <tr>
    <td align="right">&nbsp;</td>
-   <td align="center">&nbsp;</td>
+   <td align="center"><math>=</math></td>
    <td align="left">
-<math>
+<math>\frac{d^2x}{d\eta^2} + \biggl[ \frac{2(1 + \eta\cot\eta)}{\eta} \biggr] \frac{dx}{d\eta}
-+ \biggl[ -\frac{6}{\eta^4}  + \frac{6 \cot\eta}{\eta^3 } \biggr]
++ \biggl[ \frac{\eta ~\omega^2_\mathrm{Chatterji}}{\sin\eta}
-+ \biggl[ 2\cot\eta \biggr] \biggl[ \frac{3}{\eta^3}  - \frac{3 \cot\eta}{\eta^2 } \biggr]
++ \frac{2 \alpha (\eta\cot\eta-1)}{\eta^2}\biggr]  x \, ,</math>
-+\frac{18}{\eta^4}
-- \frac{6}{\eta^2}
-+ \biggl[ 2\cot\eta \biggr]\biggl[
-- \frac{3\cot^2\eta}{\eta}
-- \frac{3\cot\eta}{\eta^2}
-- \frac{3}{\eta}
--\frac{ 3}{\eta^3}
-\biggr]
-</math>
 </td>
 </tr>
+</table>
+which, again apart from notation, is identical to equation (2) of {{ Chatterji51 }}; see also the (unnumbered) equation in the middle of the left-hand-column of p. 223 in {{ MF85b }}.
+</td></tr>
+</table>
+If we set <math>\gamma = (n+1)/n = 2</math> (and correspondingly set <math>\alpha = [3-4/\gamma] = +1)</math>, the <math>n=1</math> LAWE we becomes,
+<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right">&nbsp;</td>
+   <td align="right"><math>0</math></td>
    <td align="center"><math>=</math></td>
    <td align="left">
-<math>
+<math>\frac{d^2x}{d\eta^2} + \biggl\{ 4 - 2 \biggl[1 - \eta\cot(\eta - B) \biggr] \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
-\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
++ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{A\sin(\eta-B)}
-\biggl[ 1  - \eta \cot\eta \biggr]
+- \biggl[1 - \eta\cot(\eta - B) \biggr]\biggr\}  \frac{x}{\eta^2}</math>
-+
-\biggl[ 2\cot\eta \biggr]  \biggl[
--\frac{3}{\eta^3}  + \frac{6\cot\eta}{\eta^2} + \frac{3}{\eta} + \frac{3\cot^2\eta}{\eta}
-\biggr]
-</math>
 </td>
 </tr>
@@ Line 1,872: / Line 1,982: @@
 <tr>
    <td align="right">&nbsp;</td>
-   <td align="center">&nbsp;</td>
+   <td align="center"><math>=</math></td>
    <td align="left">
-<math>
+<math>\frac{d^2x}{d\eta^2} + 2\biggl\{ 1 + \eta\cot(\eta - B) \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
-+ \biggl[ 2\cot\eta \biggr]\biggl[\frac{3}{\eta^3}
++ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{A\sin(\eta-B)}
-- \frac{3\cot^2\eta}{\eta}
+- 1 + \eta\cot(\eta - B) \biggr\}  \frac{x}{\eta^2} \, .</math>
-- \frac{6\cot\eta}{\eta^2}
+</td>
-- \frac{3}{\eta}
-\biggr]
-</math>
-</td>
-</tr>
-<tr>
-  <td align="right">&nbsp;</td>
-  <td align="center"><math>=</math></td>
-  <td align="left">
-<math>
-\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
-\biggl[ 1  - \eta \cot\eta \biggr] \, .
-</math>
-</td>
 </tr>
 </table>
+Multiplying through by <math>\phi</math>, we can write,
-</td></tr></table>
-the <math>n=1</math> LAWE reduces to &hellip;
 <table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right">LAWE</td>
+   <td align="right"><math>\biggl[ \frac{A\sin(\eta-B)}{\eta}\biggr]\frac{d^2x}{d\eta^2} </math></td>
    <td align="center"><math>=</math></td>
    <td align="left">
 <math>
-\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
+- \frac{2A}{\eta}\biggl\{ \sin(\eta - B) + \eta\cos(\eta - B) \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
-\biggl[ 1  - \eta \cot\eta \biggr] \, .
++ \frac{2A}{\eta} \biggl\{ \sin(\eta - B) - \eta\cos(\eta - B) \biggr\}  \frac{x}{\eta^2}
+- 2 \biggl( \frac{\sigma_c^2}{12} \biggr) x \, .
 </math>
 </td>
@@ Line 1,914: / Line 2,006: @@
 </table>
-ASSESSMENT:&nbsp;
+====Discrete Form  of LAWE====
-<ol>
+In order to integrate this 2<sup>nd</sup>-order ODE numerically, we will build from the [[SSC/Stability/Polytropes#Numerical_Integration_from_the_Center,_Outward|more general expression for polytropes used in our separate development of a finite-difference scheme]], namely,
-  <li>
-If we set <math>\sigma_c^2 = 0</math>, the right-hand-side of this expression goes to zero &#8212; and, hence, the <math>n=1</math> LAWE is satisfied &#8212; for any chosen truncation radius in the range, <math>0 < \eta_i < \pi</math>.  (We have not included the ''isolated'' <math>n=1</math> polytrope because <math>x_P</math> blows up at its surface, <math>\eta_i = \pi</math>.)
-  </li>
-  <li>
-At the surface, <math>\eta_i</math>, the slope of this trial eigenfunction is,
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>\frac{1}{3} \cdot \frac{dx_P}{d\eta} \biggr|_i</math>
+<math>\theta_i {x_i''}</math>
    </td>
    <td align="center">
@@ Line 1,932: / Line 2,018: @@
    </td>
    <td align="left">
-<math>
+<math>- \biggl[4\theta_i - (n+1)\xi_i (- \theta^')_i\biggr] \frac{x_i'}{\xi_i}
-\biggl[\frac{\cot\eta_i}{\eta_i^2} + \frac{1}{\eta_i} + \frac{\cot^2\eta_i}{\eta_i}\biggr] -\frac{2}{\eta_i^3}
+- (n+1)\biggl[ \frac{\sigma_c^2}{6\gamma_g}  -
-\, .
+\frac{\alpha}{\xi_i } (- \theta^')_i\biggr]  x_i \, .</math>
-</math>
    </td>
 </tr>
 </table>
-By contrast, as stated above, the eigenvalue problem will be properly solved only if the surface slope is,
+Making the notation substitutions, <math>(\xi, \theta) \rightarrow (\eta, \phi)</math>, we have instead,
-<table border="0" align="center" cellpadding="5">
+<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>- \frac{d\ln x}{d\ln \eta} \biggr|_\mathrm{surf}</math>
+<math>\phi_i {x_i''}</math>
+  </td>
+  <td align="center">
+<math>=</math>
    </td>
-  <td align="center">=</td>
    <td align="left">
-<math>
+<math>- \biggl[4\phi_i - (n+1)\eta_i (- \phi^')_i\biggr] \frac{x_i'}{\eta_i}
-+ \frac{\cancelto{0}{\sigma_c^2}}{12}
+- (n+1)\biggl[ \frac{\sigma_c^2}{6\gamma_g}  -
-\biggl[ \frac{\eta^3}{(\eta \cos\eta - \sin\eta)}\biggr]_{\eta=\pi}
+\frac{\alpha}{\eta_i } (- \phi^')_i\biggr]  x_i \, .</math>
-= 1
-</math>
    </td>
 </tr>
+</table>
+Now, adopting the finite-difference expressions,
+<table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>\Rightarrow ~~~ \frac{1}{3} \cdot \frac{dx_P}{d\eta} \biggr|_\mathrm{surf}</math>
+<math>x_i'</math>
+  </td>
+  <td align="center">
+<math>\approx</math>
    </td>
-  <td align="center">=</td>
    <td align="left">
-<math>
+<math>\frac{x_+ - x_-}{2 \Delta_\eta} \, ,</math>&nbsp; &nbsp; and,
-- \frac{x_P}{3\eta}\biggr|_i
-</math>
    </td>
 </tr>
@@ Line 1,970: / Line 2,059: @@
 <tr>
    <td align="right">
-&nbsp;
+<math>
+x_i''
+</math>
+  </td>
+  <td align="center">
+<math>\approx</math>
    </td>
-  <td align="center">=</td>
    <td align="left">
-<math>
+<math>\frac{x_+ - 2x_i + x_-}{\Delta_\eta^2} \, ,</math>
-- \frac{1}{\eta_i^3} \biggl[ 1 - \eta_i \cot\eta_i \biggr]
-=
-\frac{\cot\eta_i}{\eta_i^2} - \frac{1}{\eta_i^3} \, .
-</math>
    </td>
 </tr>
 </table>
-These two slopes do not appear to be the same, for any allowed choice of <math>\eta_i</math>.  We conclude, therefore, that no model along the sequence of pressure-truncated <math>n=1</math> polytropes is marginally unstable.
+</div>
-  </li>
+<span id="DiscreteLAWE">the discrete form of the LAWE becomes,</span>
-</ol>
-====Determining Discrete Representation of Eigenfunction====
-Let's numerically integrate the [[#DiscreteLAWE|discrete form of the <math>n=1</math> LAWE]] over the radial coordinate range, <math>0 \le \eta_i \le \eta_s</math>.  Following our [[SSC/Stability/Polytropes#KickStart|discussion of the more general polytropic case]], we will kickstart integration from the center, outward, via the expression,
 <table border="0" cellpadding="5" align="center">
@@ Line 1,994: / Line 2,078: @@
 <tr>
    <td align="right">
-<math>
+<math>x_+ \overbrace{\biggl[2\phi_i +\frac{4\Delta_\eta \phi_i}{\eta_i} - \Delta_\eta (n+1)(- \phi^')_i\biggr]}^{\mathrm{TERM1}} </math>
-x_2
-</math>
    </td>
    <td align="center">
@@ Line 2,003: / Line 2,085: @@
    <td align="left">
 <math>
-x_1 \biggl[ 1 - \frac{(n+1) \mathfrak{F}  \Delta_\eta^2}{60} \biggr] \, ,</math>
+x_- \overbrace{\biggl[\frac{4\Delta_\eta \phi_i}{\eta_i} - \Delta_\eta (n+1)(- \phi^')_i - 2\phi_i\biggr]}^{\mathrm{TERM2}}
-  </td>
++  x_i \overbrace{\biggl\{4\phi_i - \frac{\Delta_\eta^2(n+1)}{3}\biggl[ \frac{\sigma_c^2}{\gamma_g}  -
-<td align="center">&nbsp; &nbsp; &nbsp; where, &nbsp; &nbsp; &nbsp; </td>
+\alpha \biggl(- \frac{3\phi^'}{\eta}\biggr)_i\biggr]  \biggr\}}^{\mathrm{TERM3}} \, .</math>
-  <td align="right">
-<math>
-\mathfrak{F}
-</math>
-  </td>
-  <td align="center">
-<math>\equiv</math>
-  </td>
-  <td align="left">
-<math>
-\biggl[ \frac{\sigma_c^2}{\gamma_g}  - 2\alpha\biggr] \, .</math>
    </td>
 </tr>
 </table>
-Here, we will restrict our investigation to the case where <math>\gamma_g = (n+1)/n = 2</math>, in which case, <math>\alpha = (3-4/\gamma_g) = +1</math>, <math>\mathfrak{F} = (\sigma_c^2 -4)/2</math>, and
+When applied specifically to an <math>n=1</math>, polytropic configuration, we should insert the following specific expressions:
 <table border="0" cellpadding="5" align="center">
 <tr>
    <td align="right">
-<math>
+<math>\gamma_g</math>
-x_2
-</math>
    </td>
    <td align="center">
@@ Line 2,035: / Line 2,104: @@
    <td align="left">
 <math>
-x_1 \biggl[ 1 - \frac{(\sigma_c^2 -4) \Delta_\eta^2}{60} \biggr] \, .</math>
++ \frac{1}{n} = 2
+\, ,</math>
    </td>
 </tr>
-</table>
-<table border="1" align="center" width="80%" cellpadding="8"><tr><td align="left">
-<font color="red">EXAMPLE:</font> &nbsp; <math>A=1</math>, <math>B=0</math>, <math>\Delta_\eta = \pi/99 = 0.031733259</math>; evaluated over range, <math>0 \le \eta_i \le \pi</math>.
-<table border="1" align="center" cellpadding="5">
 <tr>
-   <td align="center"><math>\sigma_c^2</math></td>
+   <td align="right">
-   <td align="center"><math>\mathfrak{F}</math></td>
+<math>\alpha</math>
-   <td align="center"><math>x_2</math></td>
+   </td>
-   <td align="center"><math>\phi_2</math></td>
+   <td align="center">
-   <td align="center"><math>(-\phi')_2</math></td>
+<math>=</math>
-  <td align="center">TERM1</td>
+   </td>
-  <td align="center">TERM2</td>
+   <td align="left">
-   <td align="center">TERM3</td>
+<math>
-  <td align="center"><math>x_3</math></td>
+- \frac{4}{\gamma_g} = +1
+\, ,</math>
+   </td>
 </tr>
 <tr>
-   <td align="center">5</td>
+   <td align="right">
-  <td align="center">+0.5</td>
+<math>\phi_i</math>
-   <td align="center">0.999983217</td>
+   </td>
-   <td align="center">0.999832175</td>
+   <td align="center">
-  <td align="center">0.010576686</td>
+<math>=</math>
-  <td align="center">5.998321784</td>
+   </td>
-  <td align="center">1.998993085</td>
+   <td align="left">
-  <td align="center">3.998992898</td>
+<math>
-  <td align="center">0.999932829</td>
+A \biggl[ \frac{\sin(\eta_i-B)}{\eta_i}\biggr] \, ,
-</tr>
-</table>
-</td></tr></table>
-=====Isolated n = 1 Polytrope=====
-If we integrate all the way out to the natural, zero-pressure surface of our <math>n = 1</math> polytrope, then <math>\eta_s = \pi</math> and &#8212; as derived in our [[SSC/Structure/Polytropes#Summary|discussion of the equilibrium structure of n = 1 polytropes]] &#8212; <math>(\rho_c/\bar\rho) = \pi^2/3</math>.  In line with our discussion of [[SSC/Stability/n3PolytropeLAWE#Schwarzschild_(1941)|Schwarzschild's model of oscillations in <math>n=3</math> polytropes]], we therefore expect the boundary condition at the surface of our <math>n=1</math> configurations to be given by the expression,
-<table border="0" align="center" cellpadding="8">
-<tr>
-  <td align="right"><math>-\frac{d\ln x}{d\ln \eta}\biggr|_\mathrm{surf}</math></td>
-   <td align="center"><math>=</math></td>
-   <td align="left">
-<math>
--~\frac{1}{2}\biggl\{ \biggl[ \mathfrak{F} + 2\alpha\biggr]\biggl(\frac{\rho_c}{\bar\rho}\biggr) - 2\alpha \biggr\}
 </math>
    </td>
@@ Line 2,085: / Line 2,138: @@
 <tr>
-   <td align="right">&nbsp;</td>
+   <td align="right">
-   <td align="center"><math>=</math></td>
+<math>(-\phi')_i</math>
+  </td>
+   <td align="center">
+<math>=</math>
+  </td>
    <td align="left">
 <math>
-- \biggl(\frac{\sigma_c^2 \pi^2}{12}\biggr)  \, ,
+\frac{A}{\eta_i^2} \biggl[\sin(\eta_i-B) - \eta_i \cos(\eta_i - B) \biggr] \, .
 </math>
    </td>
 </tr>
 </table>
-as [[#Review_of_Trial_Analytic_Eigenfunction|reviewed immediately above]].  This should be compared with the finite-difference representation of the logarithmic derivative, namely,
-<table border="0" cellpadding="5" align="center">
+===Pressure-Truncated n = 1 Polytrope===
+In the case of an ''isolated'' <math>n=1</math> polytrope, we must set <math>B = 0</math>; in addition, it is customary to set <math>A = 1</math>.  The relevant LAWE is, then,
+<table border=0 cellpadding=2 align="center">
 <tr>
-   <td align="right">
+   <td align="right"><math>0</math></td>
-<math>+\frac{\Delta\ln x}{\Delta\ln \xi} \biggr|_\mathrm{surface}</math>
+   <td align="center"><math>=</math></td>
-  </td>
-   <td align="center">
-<math>\approx</math>
-  </td>
    <td align="left">
-<math>\frac{\xi_\mathrm{max}}{x_N} \biggl[ \frac{x_{N+1}-x_{N-1}}{2\Delta_\xi} \biggr] \, .</math>
+<math>\frac{d^2x}{d\eta^2} + 2\biggl\{ 1 + \eta\cot(\eta) \biggr\} \frac{1}{\eta} \cdot \frac{dx}{d\eta}
-  </td>
++ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{\sin(\eta)}
+- 1 + \eta\cot(\eta) \biggr\}  \frac{x}{\eta^2} \, .</math>
+</td>
 </tr>
 </table>
-<font color="red">CAUTION!</font> &nbsp; &nbsp; Because, for each ''guess'' of <math>\sigma_c^2</math>, the eigenfunction climbs (or plummets) rapidly as we approach the surface, in practice we evaluated the finite-difference representation of the logarithmic derivative at a zone location that is a bit inside of the actual surface; for example, when we divided the equilibrium configuration into <math>N = 100</math> grid zones, we evaluated the "surface" derivative at zone number 97.
-Here we have adopted an analysis that closely resembles our [[SSC/Stability/n3PolytropeLAWE#Numerical_Integration|discussion of the analysis of <math>n=3</math> polytropes]] that was published by {{ Schwarzschild41 }}. Here we have divided our model into <math>N = 100</math> radial zones and, using this algorithm, integrated the LAWE from the center of the configuration to the surface, for <math>\alpha = +1</math>, and approximately 40 different chosen values of the frequency parameter across the range, <math>-2 \le \mathfrak{F} \le + 18</math>.  The radial displacement functions resulting from these integrations are presented in the following figure as an animation sequence.  The specified value of <math>\mathfrak{F}</math> is displayed at the top of each animation frame, and the resulting displacement function, <math>x(\eta)</math>, is traced by the small, red circular markers in each frame.
+====Review of Trial Analytic Eigenfunction====
-<table border="1" align="center" cellpadding="5">
+This is the same 2<sup>nd</sup>-order ODE that we derived in a [[SSC/Stability/n1PolytropeLAWE#WorkInProgress|separate discussion]]; there it was accompanied by the [[SSC/Stability/Polytropes#Boundary_Conditions|surface boundary condition]],
+<table border="0" align="center" cellpadding="5">
 <tr>
-   <td align="center" colspan="4">Four Modes of Oscillation<br />of an Isolated, <math>n=1</math> Polytrope</td>
+   <td align="right">
+<math>- \frac{d\ln x}{d\ln \xi} \biggr|_\mathrm{surf}</math>
+  </td>
+  <td align="center">=</td>
+  <td align="left">
+<math>
+\biggl( \frac{3-n}{n+1}\biggr) + \frac{n\sigma_c^2}{6(n+1)}
+\biggl[ \frac{\xi}{\theta'}\biggr]_\mathrm{surf}
+</math>
+  </td>
 </tr>
 <tr>
-   <td align="center">Mode</td>
+   <td align="right">
-   <td align="center"><math>\sigma_c^2</math></td>
+<math>\Rightarrow ~~~ - \frac{d\ln x}{d\ln \eta} \biggr|_\mathrm{surf}</math>
-   <td align="center">Neg. Slope<br><math>1 - (\sigma_c^2\pi^2/12)</math></td>
+  </td>
-  <td align="center"><math>\mathfrak{F} = \frac{\sigma_c^2}{\gamma_g} - 2\alpha</math></td>
+   <td align="center">=</td>
-</tr>
+   <td align="left">
-<tr>
+<math>
-  <td align="center">Fundamental</td>
++ \frac{\sigma_c^2}{12}
-   <td align="center">2.2405295</td>
+\biggl[ \frac{\eta^3}{(\eta \cos\eta - \sin\eta)}\biggr]_{\eta=\pi}
-   <td align="center">3.1287618</td>
+=
-   <td align="center">-0.879735</td>
+- \frac{\pi^2 \sigma_c^2}{12} \, .
-</tr>
+</math>
-<tr>
+  </td>
-  <td align="center">1<sup>st</sup> Overtone</td>
+</tr>
-  <td align="center">6.340767</td>
+</table>
-   <td align="center">-32.06757</td>
-   <td align="center">1.1703835</td>
+From, for example, a separate [[SSC/Stability/n1PolytropeLAWE#Succinct_Demonstration|succinct demonstration]], we appreciate that if the displacement function is assumed to be,
-</tr>
-<tr>
+<table border="0" cellpadding="5" align="center">
-   <td align="center">2<sup>nd</sup> Overtone</td>
-   <td align="center">13.694927</td>
+<tr>
-  <td align="center">-153.2545</td>
+   <td align="right">
-   <td align="center">4.8474635</td>
+<math>x_P</math>
-</tr>
+  </td>
-<tr>
+   <td align="center">
-  <td align="center">3<sup>rd</sup> Overtone</td>
+<math>=</math>
-   <td align="center">28.462829</td>
+  </td>
-   <td align="center">-665.3074</td>
+   <td align="left">
-  <td align="center">12.231415</td>
+<math>\frac{3}{\eta^2} \biggl[ 1 - \eta \cot\eta \biggr] </math>
-</tr>
+  </td>
+</tr>
-<tr><td align="center" colspan="4">
+</table>
-[[File:N1osc06.gif|600px|Animated gif showing oscillation modes for n = 1 polytrope]]
-</td></tr></table>
+<table border="1" align="center" cellpadding="5" width="80%"><tr><td align="left">
+&hellip; that is,
-=====Pressure-Truncated n = 1 Polytrope=====
-Drawing from an [[SSC/Stability/NeutralMode#Part_2|accompanying discussion]], if the polytropic configuration is truncated by the pressure, <math>P_e</math>, of a hot, tenuous external medium, then the solution to the LAWE is subject to the outer boundary condition,
+<table border="0" cellpadding="5" align="center">
-<table border="0" cellpadding="5" align="center">
+<tr>
+   <td align="right">
-<tr>
+<math>x_P</math>
-   <td align="right">
+   </td>
-<math>
+   <td align="center">
--\frac{d\ln x}{d\ln\eta}
+<math>=</math>
-</math>
+  </td>
-   </td>
+   <td align="left">
-   <td align="center">
+<math>\frac{3}{\eta^2}  - \frac{3 \cos\eta}{\eta \sin\eta} \, , </math>
-<math>=</math>
+   </td>
-   </td>
+</tr>
-   <td align="left">
+</table>
-<math>3</math> &nbsp; &nbsp; at &nbsp; &nbsp; <math>\eta = \tilde\eta</math>.
-   </td>
+in which case,
-</tr>
-</table>
+<table border="0" cellpadding="5" align="center">
-===Bipolytropic Envelope (Trial Simplification)===
+<tr>
+   <td align="right">
-For the <math>n=1</math> envelope of a <math>(n_c, n_e) = (5, 1)</math> bipolytrope, the relevant LAWE is,
+<math>\frac{dx_P}{d\eta}</math>
+  </td>
+   <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+-\frac{6}{\eta^3} + 3\biggl[\frac{\cos\eta}{\eta^2\sin\eta} + \frac{1}{\eta} + \frac{\cos^2\eta}{\eta\sin^2\eta}\biggr]
+\, ,
+</math>
+  </td>
+</tr>
+</table>
+and,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>\frac{d^2x_P}{d\eta^2}</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
++\frac{18}{\eta^4}
++
+\frac{d}{d\eta}\biggl[ \frac{\cos\eta}{\eta^2\sin\eta} \biggr]
++ 3\frac{d}{d\eta}\biggl[ \frac{1}{\eta} \biggr]
++ 3\frac{d}{d\eta}\biggl[ \frac{\cos^2\eta}{\eta\sin^2\eta} \biggr]
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">
+&nbsp;
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
++\frac{18}{\eta^4}
+-
+\biggl[ \frac{ 2\cos\eta}{\eta^3\sin\eta} + \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{\sin\eta}{\eta^2\sin\eta} \biggr]
+- \biggl[ \frac{3}{\eta^2} \biggr]
+- 3\biggl[ \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{2\cos^3\eta}{\eta\sin^3\eta} + \frac{2\cos\eta}{\eta\sin\eta} \biggr]
+\, .
+</math>
+  </td>
+</tr>
+</table>
+Hence,
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right">LAWE</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl\{ \frac{2}{\eta} + \frac{2\cos\eta}{\sin\eta} \biggr\}  \biggl\{
+-\frac{6}{\eta^3} + \biggl[\frac{3\cos\eta}{\eta^2\sin\eta} + \frac{3}{\eta} + \frac{3\cos^2\eta}{\eta\sin^2\eta}\biggr]
+\biggr\}
++ 2 \biggl\{ \biggl( \frac{\sigma_c^2}{12} \biggr)  \frac{\eta^3}{\sin(\eta)}
+- 1 + \frac{\eta\cos\eta}{\sin\eta} \biggr\} \biggl[ \frac{3}{\eta^4}  - \frac{3 \cos\eta}{\eta^3 \sin\eta} \biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center">&nbsp;</td>
+  <td align="left">
+<math>
++\frac{18}{\eta^4}
+-
+\biggl[ \frac{ 2\cos\eta}{\eta^3\sin\eta} + \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{\sin\eta}{\eta^2\sin\eta} \biggr]
+- \biggl[ \frac{3}{\eta^2} \biggr]
+- 3\biggl[ \frac{\cos^2\eta}{\eta^2\sin^2\eta} + \frac{2\cos^3\eta}{\eta\sin^3\eta} + \frac{2\cos\eta}{\eta\sin\eta} \biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl[ \frac{2}{\eta} + 2\cot\eta \biggr]  \biggl[
+-\frac{6}{\eta^3} + \frac{3\cot\eta}{\eta^2} + \frac{3}{\eta} + \frac{3\cot^2\eta}{\eta}
+\biggr]
++ \biggl\{ \biggl( \frac{\sigma_c^2}{6} \biggr)  \frac{\eta^3}{\sin\eta}
+\biggr\} \biggl[ \frac{3}{\eta^4}  - \frac{3 \cot\eta}{\eta^3 } \biggr]
++ \biggl[- 2 + 2\eta\cot\eta \biggr] \biggl[ \frac{3}{\eta^4}  - \frac{3 \cot\eta}{\eta^3 } \biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center">&nbsp;</td>
+  <td align="left">
+<math>
++\frac{18}{\eta^4}
+-
+\biggl[ \frac{ 6\cot\eta}{\eta^3} + \frac{3\cot^2\eta}{\eta^2} + \frac{3}{\eta^2} \biggr]
+- \biggl[ \frac{3}{\eta^2} \biggr]
+- \biggl[ \frac{3\cot^2\eta}{\eta^2} + \frac{6\cot^3\eta}{\eta} + \frac{6\cot\eta}{\eta} \biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
+\biggl[ 1  - \eta \cot\eta \biggr]
++
+\biggl[ -\frac{12}{\eta^4} + \frac{6}{\eta^2} \biggr]
++
+\biggl[ 2\cot\eta \biggr]\biggl[ \frac{3}{\eta^3}  + \frac{3\cot\eta}{\eta^2} \biggr]
++
+\biggl[ 2\cot\eta \biggr]  \biggl[
+-\frac{6}{\eta^3} + \frac{3\cot\eta}{\eta^2} + \frac{3}{\eta} + \frac{3\cot^2\eta}{\eta}
+\biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center">&nbsp;</td>
+  <td align="left">
+<math>
++ \biggl[ -\frac{6}{\eta^4}  + \frac{6 \cot\eta}{\eta^3 } \biggr]
++ \biggl[ 2\cot\eta \biggr] \biggl[ \frac{3}{\eta^3}  - \frac{3 \cot\eta}{\eta^2 } \biggr]
++\frac{18}{\eta^4}
+- \frac{6}{\eta^2}
++ \biggl[ 2\cot\eta \biggr]\biggl[
+- \frac{3\cot^2\eta}{\eta}
+- \frac{3\cot\eta}{\eta^2}
+- \frac{3}{\eta}
+-\frac{ 3}{\eta^3}
+\biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
+\biggl[ 1  - \eta \cot\eta \biggr]
++
+\biggl[ 2\cot\eta \biggr]  \biggl[
+-\frac{3}{\eta^3}  + \frac{6\cot\eta}{\eta^2} + \frac{3}{\eta} + \frac{3\cot^2\eta}{\eta}
+\biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center">&nbsp;</td>
+  <td align="left">
+<math>
++ \biggl[ 2\cot\eta \biggr]\biggl[\frac{3}{\eta^3}
+- \frac{3\cot^2\eta}{\eta}
+- \frac{6\cot\eta}{\eta^2}
+- \frac{3}{\eta}
+\biggr]
+</math>
+</td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
+\biggl[ 1  - \eta \cot\eta \biggr] \, .
+</math>
+</td>
+</tr>
+</table>
+</td></tr></table>
+the <math>n=1</math> LAWE reduces to &hellip;
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right">LAWE</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\biggl\{ \biggl( \frac{\sigma_c^2}{2} \biggr)  \frac{1}{\eta \sin\eta} \biggr\}
+\biggl[ 1  - \eta \cot\eta \biggr] \, .
+</math>
+</td>
+</tr>
+</table>
+ASSESSMENT:&nbsp;
+<ol>
+  <li>
+If we set <math>\sigma_c^2 = 0</math>, the right-hand-side of this expression goes to zero &#8212; and, hence, the <math>n=1</math> LAWE is satisfied &#8212; for any chosen truncation radius in the range, <math>0 < \eta_i < \pi</math>.  (We have not included the ''isolated'' <math>n=1</math> polytrope because <math>x_P</math> blows up at its surface, <math>\eta_i = \pi</math>.)
+  </li>
+  <li>
+At the surface, <math>\eta_i</math>, the slope of this trial eigenfunction is,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>\frac{1}{3} \cdot \frac{dx_P}{d\eta} \biggr|_i</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+\biggl[\frac{\cot\eta_i}{\eta_i^2} + \frac{1}{\eta_i} + \frac{\cot^2\eta_i}{\eta_i}\biggr] -\frac{2}{\eta_i^3}
+\, .
+</math>
+  </td>
+</tr>
+</table>
+By contrast, as stated above, the eigenvalue problem will be properly solved only if the surface slope is,
+<table border="0" align="center" cellpadding="5">
+<tr>
+  <td align="right">
+<math>- \frac{d\ln x}{d\ln \eta} \biggr|_\mathrm{surf}</math>
+  </td>
+  <td align="center">=</td>
+  <td align="left">
+<math>
++ \frac{\cancelto{0}{\sigma_c^2}}{12}
+\biggl[ \frac{\eta^3}{(\eta \cos\eta - \sin\eta)}\biggr]_{\eta=\pi}
+= 1
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">
+<math>\Rightarrow ~~~ \frac{1}{3} \cdot \frac{dx_P}{d\eta} \biggr|_\mathrm{surf}</math>
+  </td>
+  <td align="center">=</td>
+  <td align="left">
+<math>
+- \frac{x_P}{3\eta}\biggr|_i
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">
+&nbsp;
+  </td>
+  <td align="center">=</td>
+  <td align="left">
+<math>
+- \frac{1}{\eta_i^3} \biggl[ 1 - \eta_i \cot\eta_i \biggr]
+=
+\frac{\cot\eta_i}{\eta_i^2} - \frac{1}{\eta_i^3} \, .
+</math>
+  </td>
+</tr>
+</table>
+These two slopes do not appear to be the same, for any allowed choice of <math>\eta_i</math>.  We conclude, therefore, that no model along the sequence of pressure-truncated <math>n=1</math> polytropes is marginally unstable.
+  </li>
+</ol>
+====Determining Discrete Representation of Eigenfunction====
+Let's numerically integrate the [[#DiscreteLAWE|discrete form of the <math>n=1</math> LAWE]] over the radial coordinate range, <math>0 \le \eta_i \le \eta_s</math>.  Following our [[SSC/Stability/Polytropes#KickStart|discussion of the more general polytropic case]], we will kickstart integration from the center, outward, via the expression,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>
+x_2
+</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+x_1 \biggl[ 1 - \frac{(n+1) \mathfrak{F}  \Delta_\eta^2}{60} \biggr] \, ,</math>
+  </td>
+<td align="center">&nbsp; &nbsp; &nbsp; where, &nbsp; &nbsp; &nbsp; </td>
+  <td align="right">
+<math>
+\mathfrak{F}
+</math>
+  </td>
+  <td align="center">
+<math>\equiv</math>
+  </td>
+  <td align="left">
+<math>
+\biggl[ \frac{\sigma_c^2}{\gamma_g}  - 2\alpha\biggr] \, .</math>
+  </td>
+</tr>
+</table>
+Here, we will restrict our investigation to the case where <math>\gamma_g = (n+1)/n = 2</math>, in which case, <math>\alpha = (3-4/\gamma_g) = +1</math>, <math>\mathfrak{F} = (\sigma_c^2 -4)/2</math>, and
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>
+x_2
+</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+x_1 \biggl[ 1 - \frac{(\sigma_c^2 -4) \Delta_\eta^2}{60} \biggr] \, .</math>
+  </td>
+</tr>
+</table>
+<table border="1" align="center" width="80%" cellpadding="8"><tr><td align="left">
+<font color="red">EXAMPLE:</font> &nbsp; <math>A=1</math>, <math>B=0</math>, <math>\Delta_\eta = \pi/99 = 0.031733259</math>; evaluated over range, <math>0 \le \eta_i \le \pi</math>.
+<table border="1" align="center" cellpadding="5">
+<tr>
+  <td align="center"><math>\sigma_c^2</math></td>
+  <td align="center"><math>\mathfrak{F}</math></td>
+  <td align="center"><math>x_2</math></td>
+  <td align="center"><math>\phi_2</math></td>
+  <td align="center"><math>(-\phi')_2</math></td>
+  <td align="center">TERM1</td>
+  <td align="center">TERM2</td>
+  <td align="center">TERM3</td>
+  <td align="center"><math>x_3</math></td>
+</tr>
+<tr>
+  <td align="center">5</td>
+  <td align="center">+0.5</td>
+  <td align="center">0.999983217</td>
+  <td align="center">0.999832175</td>
+  <td align="center">0.010576686</td>
+  <td align="center">5.998321784</td>
+  <td align="center">1.998993085</td>
+  <td align="center">3.998992898</td>
+  <td align="center">0.999932829</td>
+</tr>
+</table>
+</td></tr></table>
+=====Isolated n = 1 Polytrope=====
+If we integrate all the way out to the natural, zero-pressure surface of our <math>n = 1</math> polytrope, then <math>\eta_s = \pi</math> and &#8212; as derived in our [[SSC/Structure/Polytropes#Summary|discussion of the equilibrium structure of n = 1 polytropes]] &#8212; <math>(\rho_c/\bar\rho) = \pi^2/3</math>.  In line with our discussion of [[SSC/Stability/n3PolytropeLAWE#Schwarzschild_(1941)|Schwarzschild's model of oscillations in <math>n=3</math> polytropes]], we therefore expect the boundary condition at the surface of our <math>n=1</math> configurations to be given by the expression,
+<table border="0" align="center" cellpadding="8">
+<tr>
+  <td align="right"><math>-\frac{d\ln x}{d\ln \eta}\biggr|_\mathrm{surf}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+-~\frac{1}{2}\biggl\{ \biggl[ \mathfrak{F} + 2\alpha\biggr]\biggl(\frac{\rho_c}{\bar\rho}\biggr) - 2\alpha \biggr\}
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+- \biggl(\frac{\sigma_c^2 \pi^2}{12}\biggr)  \, ,
+</math>
+  </td>
+</tr>
+</table>
+as [[#Review_of_Trial_Analytic_Eigenfunction|reviewed immediately above]].
+<table border="1" width="80%" cellpadding="8" align="center">
+<tr>
+  <td align="center" bgcolor="pink">
+{{ Chatterji51 }} &#8212; STEP 3
+  </td>
+</tr>
+<tr><td align="left">
+Here we examine what the boundary condition should be at the surface of an isolated <math>n=1</math> polytrope.  Given that, quite generally in the context of isolated polytropes,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>\alpha</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+- \frac{4}{\gamma} \, ,
+</math>
+  </td>
+<td align="center">&nbsp; &nbsp; &nbsp; and, &nbsp; &nbsp; &nbsp;</td>
+  <td align="right">
+<math>\mathfrak{F}</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+\frac{\sigma_c^2}{\gamma} - 2\alpha \, ,
+</math>
+  </td>
+</tr>
+</table>
+the surface boundary condition is,
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right"><math>-\frac{d\ln x}{d\ln \eta}\biggr|_\mathrm{surf}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+-~\frac{1}{2}\biggl\{ \biggl[ \mathfrak{F} + 2\alpha\biggr]\biggl(\frac{\rho_c}{\bar\rho}\biggr) - 2\alpha \biggr\}
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+-~\frac{\sigma_c^2}{2\gamma}\biggl(\frac{\rho_c}{\bar\rho}\biggr)  + 3 - \frac{4}{\gamma}
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">&nbsp;</td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+- \frac{1}{\gamma}\biggl[ 4 + \frac{\sigma_c^2}{2}\biggl(\frac{\rho_c}{\bar\rho}\biggr) \biggr] \, .
+</math>
+  </td>
+</tr>
+</table>
+<font color="maroon"><b>Considerations:</b></font>
+<ol type="A">
+<li>For an isolated <math>n=1</math> polytrope, the central-to-mean density is, <math>\rho_c/\bar\rho = \pi^2/3</math>.  Hence,
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right"><math>\biggl\{ -\frac{d\ln x}{d\ln \eta}\biggr|_\mathrm{surf} \biggr\}_{n=1}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+- \frac{1}{\gamma}\biggl[ 4 + \frac{\pi^2 \sigma_c^2}{6}\biggr] \, .
+</math>
+  </td>
+</tr>
+</table>
+</li>
+<li>If, in addition, we set <math>\gamma = (n+1)/n = 2 ~\Rightarrow ~\alpha=+1</math>, then,
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right"><math>\biggl\{ -\frac{d\ln x}{d\ln \eta}\biggr|_\mathrm{surf} \biggr\}_{n=1, ~\alpha=+1}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+- \frac{1}{2}\biggl[ 4 + \frac{\pi^2 \sigma_c^2}{6}\biggr] = 1 - \frac{\pi^2 \sigma_c^2}{12} \, .
+</math>
+  </td>
+</tr>
+</table>
+</li>
+<li>If we set <math>\gamma = [4/(3-\alpha)]</math> for all other values of <math>\alpha</math>, we can write,
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right"><math>\biggl\{ -\frac{d\ln x}{d\ln \eta}\biggr|_\mathrm{surf} \biggr\}_{n=1, ~\alpha}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+- (3-\alpha)\biggl[ 1 + \frac{\pi^2 \sigma_c^2}{24}\biggr]
+=
+\alpha - (3-\alpha)\biggl[ \frac{\pi^2 \sigma_c^2}{24}\biggr]\, .
+</math>
+  </td>
+</tr>
+</table>
+</li>
+</ol>
+----
+At the bottom of p. 469 of his article, {{ Chatterji51 }} states that, <font color="darkgreen">"&hellip; the condition for the Node to fall at the surface of the star</font> is,
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right"><math>3f + z~\frac{df}{dz}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\, ,
+</math>
+  </td>
+</tr>
+</table>
+which we interpret to mean,
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right"><math>\biggl\{ -\frac{d\ln f}{d\ln z}\biggr|_\mathrm{surf} \biggr\}_{n=1,~\alpha}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\, .
+</math>
+  </td>
+</tr>
+</table>
+He goes on to say, <font color="darkgreen">"As the adiabatic approximation breaks down near the boundary we have not strictly followed this condition."</font>
+</td></tr>
+</table>
+This should be compared with the finite-difference representation of the logarithmic derivative, namely,
+<table border="0" cellpadding="5" align="center">
+<tr>
+  <td align="right">
+<math>+\frac{\Delta\ln x}{\Delta\ln \xi} \biggr|_\mathrm{surface}</math>
+  </td>
+  <td align="center">
+<math>\approx</math>
+  </td>
+  <td align="left">
+<math>\frac{\xi_\mathrm{max}}{x_N} \biggl[ \frac{x_{N+1}-x_{N-1}}{2\Delta_\xi} \biggr] \, .</math>
+  </td>
+</tr>
+</table>
+<font color="red">CAUTION!</font> &nbsp; &nbsp; Because, for each ''guess'' of <math>\sigma_c^2</math>, the eigenfunction climbs (or plummets) rapidly as we approach the surface, in practice we evaluated the finite-difference representation of the logarithmic derivative at a zone location that is a bit inside of the actual surface; for example, when we divided the equilibrium configuration into <math>N = 100</math> grid zones, we evaluated the "surface" derivative at zone number 97.
+Here we have adopted an analysis that closely resembles our [[SSC/Stability/n3PolytropeLAWE#Numerical_Integration|discussion of the analysis of <math>n=3</math> polytropes]] that was published by {{ Schwarzschild41 }}. Here we have divided our model into <math>N = 100</math> radial zones and, using this algorithm, integrated the LAWE from the center of the configuration to the surface, for <math>\alpha = +1</math>, and approximately 40 different chosen values of the frequency parameter across the range, <math>-2 \le \mathfrak{F} \le + 18</math>.  The radial displacement functions resulting from these integrations are presented in the following figure as an animation sequence.  The specified value of <math>\mathfrak{F}</math> is displayed at the top of each animation frame, and the resulting displacement function, <math>x(\eta)</math>, is traced by the small, red circular markers in each frame.
+<table border="1" align="center" cellpadding="5">
+<tr>
+  <td align="center" colspan="4">[[File:DataFileButton02.png|right|60px|file = Dropbox/WorkFolder/Wiki edits/BiPolytrope/qAndNuMaxAug21.xlsx --- worksheet = n1Oscillations]]Four Modes of Oscillation<br />of an Isolated, <math>n=1</math> Polytrope</td>
+</tr>
+<tr>
+  <td align="center">Mode</td>
+  <td align="center"><math>\sigma_c^2</math></td>
+  <td align="center">Neg. Slope<br><math>1 - (\sigma_c^2\pi^2/12)</math></td>
+  <td align="center"><math>\mathfrak{F} = \frac{\sigma_c^2}{\gamma_g} - 2\alpha</math></td>
+</tr>
+<tr>
+  <td align="center">Fundamental</td>
+  <td align="center">2.2405295</td>
+  <td align="center">3.1287618</td>
+  <td align="center">-0.879735</td>
+</tr>
+<tr>
+  <td align="center">1<sup>st</sup> Overtone</td>
+  <td align="center">6.340767</td>
+  <td align="center">-32.06757</td>
+  <td align="center">1.1703835</td>
+</tr>
+<tr>
+  <td align="center">2<sup>nd</sup> Overtone</td>
+  <td align="center">13.694927</td>
+  <td align="center">-153.2545</td>
+  <td align="center">4.8474635</td>
+</tr>
+<tr>
+  <td align="center">3<sup>rd</sup> Overtone</td>
+  <td align="center">28.462829</td>
+  <td align="center">-665.3074</td>
+  <td align="center">12.231415</td>
+</tr>
+<tr><td align="center" colspan="4">
+[[File:DataFileButton02.png|right|60px|file = Dropbox/WorkFolder/Wiki edits/LinearPerturbation/n1Eigenvectors/MovieFrames/KeyAnimation/n1osc06.gif]]
+[[File:N1osc06.gif|600px|Animated gif showing oscillation modes for n = 1 polytrope]]
+</td></tr></table>
+<table border="1" align="center" cellpadding="8" width="90%">
+<tr>
+  <td align="center" colspan="3" bgcolor="pink">{{ Chatterji51figure }}</td>
+</tr>
+<tr>
+  <td align="center" colspan="3">''Amplitudes and frequencies of the displacement functions for three modes, assuming'' <math>\alpha = 0.6</math> and <math>\gamma = 5/3</math></td>
+</tr>
+<tr>
+  <td align="center" colspan="1">Amplitudes extracted from Chatterji's Table II (p. 468)</td>
+  <td align="center" colspan="1">Plot for comparison with Chatterji's Fig. 1 (p. 469)</td>
+  <td align="center" colspan="1">Eigenfrequencies extracted<br />from Chatterji's Table I (p. 468)</td>
+</tr>
+<tr><td align="left" width="50%">
+<div id="Chatterji51Table2Data" style="width: 100%; height: 30em; overflow: auto;">
+<pre>
+st            2nd
+Abscissa	Fundamental	Overtone	Overtone
+.0	         1.000000	1.000000	1.000000
+.1	         1.000169	0.998882	0.996820
+.2	         1.000677	0.995518	0.987281
+.3	         1.001525	0.989874	0.971386
+.4	         1.002716	0.981890	0.949136
+.5	         1.004251	0.971495	0.920555
+.6	         1.006143	0.958596	0.885671
+.7	         1.008389	0.943052	0.844515
+.8	         1.011009	0.924713	0.797168
+.9	         1.014006	0.903389	0.743728
+.0	         1.017390	0.878859	0.684350
+.1	         1.021175	0.850865	0.619257
+.2	         1.025374	0.819105	0.548757
+.3	         1.030004	0.783221	0.473277
+.4	         1.035102	0.742868	0.393396
+.5	         1.040853	0.697654	0.309941
+.6	         1.047084	0.646920	0.223844
+.7	         1.053810	0.590042	0.136419
+.8	         1.061066	0.526318	0.049379
+.9	         1.068886	0.454939       -0.035065
+.0	         1.077309	0.374974       -0.114079
+.1	         1.086374	0.285357       -0.184050
+.2	         1.096138	0.184876       -0.240444
+.3	         1.106766	0.072271       -0.277903
+.4	         1.118204      -0.054152       -0.288854
+.5	         1.130496      -0.196154       -0.264401
+.6	         1.143708      -0.355598       -0.193931
+.7	         1.157893      -0.534282       -0.065351
+.8	         1.173099      -0.733397	0.133422
+.9	         1.189288      -0.951614	0.408698
+.0	         1.206063      -1.175893	0.734701
+.1	         1.218532      -1.251806	0.780444
+</pre>
+</div>
+  </td>
+  <td align="center">
+[[File:Chatterji51Summary2.png|400px|Chatterji's Figure 1]]
+  </td>
+  <td align="center">
+<table border="0" align="center" cellpadding="8">
+<tr>
+  <td align="center">Mode</td>
+  <td align="center"><math>\omega^2_\mathrm{Chatterji}</math></td>
+  <td align="center"><math>\sigma_c^2</math></td>
+</tr>
+<tr>
+  <td align="left">Fundamental</td>
+  <td align="center" bgcolor="pink">0.231</td>
+  <td align="center">1.155</td>
+</tr>
+<tr>
+  <td align="left">1<sup>st</sup> Overtone</td>
+  <td align="center" bgcolor="pink">1.517</td>
+  <td align="center">7.585</td>
+</tr>
+<tr>
+  <td align="left">2<sup>nd</sup> Overtone</td>
+  <td align="center" bgcolor="pink">3.580</td>
+  <td align="center">17.900</td>
+</tr>
+</table>
+  </td>
+</tr>
+<tr>
+  <td align="left" colspan="3">
+The solid circular markers in the plot (center panel) show how the amplitude of the displacement function varies with radius <math>0 \le \eta < \pi</math> for three separate radial modes, according to the data provided in Table II of {{ Chatterji51 }}, which has been reproduced here in the ''scrollable'' left-hand panel.  In the plot, ''blue'' is the fundamental mode, ''red'' is the 1<sup>st</sup> overtone, ''green'' is the 2<sup>nd</sup> overtone.  The (square of the) eigenfrequency corresponding to each mode, according to Table I of {{ Chatterji51 }}, is provided in the column of the right-hand panel that is (highlighted in pink and) labeled <math>\omega^2_\mathrm{Chatterji}</math>; also listed are the corresponding values of <math>\sigma_c^2 = 3\gamma \omega^2_\mathrm{Chatterji}</math>.
+<br />&nbsp;<br />
+The smooth, solid curves in the middle-panel plot are ''not'' fits to Chatterji's data.  Rather, they result from our own, independent numerical integration of the relevant LAWE, assuming that Chatterji's published values of the (square of the) eigenfrequency are correct for all three modes.  In all three cases for the specified eigenfrequency, there is excellent agreement between our determination of the radial eigenfunction and the determination obtained by {{ Chatterji51 }}.
+  </td>
+</tr>
+</table>
+We are exceptionally pleased to find that, for each of the three modes of oscillation, the displacement function obtained via our integration of the LAWE (solid curves in the figure) runs through the discrete points recorded by {{ Chatterji51 }} (solid circular markers in the figure).  But in doing so, we find from our higher resolution model that there is an inflection point just inside the surface of the model; this is not the smooth behavior that is expected as the surface is approached.  In an effort to correct this behavior, we have changed the constraint that is applied while integrating the LAWE from the center, outward:  Instead of forcing <math>\omega^2_\mathrm{Chatterji}</math> to match the value published by {{ Chatterji51 }}, we have let the value of this oscillation frequency vary while enforcing the surface boundary condition describe above as <font color="maroon">CONSIDERATION "C"</font>.  The resulting "improved" solution is shown in the figure that follows.
+<table border="1" align="center" cellpadding="8" width="90%">
+<tr>
+  <td align="center" colspan="3" bgcolor="yellow">Our Imposed Surface Boundary Condition:  <br />
+<table border=0 cellpadding=2 align="center">
+<tr>
+  <td align="right"><math>\biggl\{ -\frac{d\ln x}{d\ln \eta}\biggr|_\mathrm{surf} \biggr\}_{n=1, ~\alpha}</math></td>
+  <td align="center"><math>=</math></td>
+  <td align="left">
+<math>
+\alpha - (3-\alpha)\biggl[ \frac{\pi^2 \sigma_c^2}{24}\biggr]\, .
+</math>
+  </td>
+</tr>
+</table>
+  </td>
+</tr>
+<tr>
+  <td align="center" colspan="3">''Amplitudes and frequencies of the displacement functions for three modes, assuming'' <math>\alpha = 0.6</math> and <math>\gamma = 5/3</math></td>
+</tr>
+<tr>
+  <td align="center" colspan="1">Amplitudes determined from our numerical integration of the LAWE</td>
+  <td align="center" colspan="1">Our version of Chatterji's Fig. 1</td>
+  <td align="center" colspan="1">Eigenfrequencies determined from our integration</td>
+</tr>
+<tr><td align="left" width="50%">
+<div id="Chatterji51Table2Data" style="width: 100%; height: 30em; overflow: auto;">
+<pre>
+Abscissa	Fundamental	1st Overtone	2nd Overtone
+.000000000	1.000000000	 1.000000000	 1.000000000
+.031733259	1.000047844	 0.999943498	 0.999786141
+.063466518	1.000089016	 0.999601959	 0.998867632
+.095199777	1.000174709	 0.999061021	 0.997382877
+.126933037	1.000294726	 0.998302963	 0.995304066
+.158666296	1.000449107	 0.997327028	 0.992631032
+.190399555	1.000637906	 0.996132244	 0.989363571
+.222132814	1.000861191	 0.994717421	 0.985501447
+.253866073	1.001119039	 0.993081149	 0.981044389
+.285599332	1.001411544	 0.991221792	 0.975992105
+.317332591	1.001738809	 0.989137492	 0.970344285
+.34906585	1.002100951	 0.986826157	 0.964100608
+.38079911	1.002498098	 0.984285466	 0.957260757
+.412532369	1.002930394	 0.981512860     0.949824425
+.444265628	1.003397993	 0.978505538	 0.94179133
+.475998887	1.003901064	 0.975260454	 0.933161228
+.507732146	1.004439786	 0.971774312	 0.923933924
+.539465405	1.005014356	 0.968043557	 0.914109296
+.571198664	1.005624981	 0.964064374	 0.903687306
+.602931923	1.006271884	 0.959832677	 0.892668024
+.634665183	1.006955299	 0.955344103	 0.881051648
+.666398442	1.007675478	 0.950594005	 0.868838527
+.698131701	1.008432684	 0.945577446	 0.856029188
+.72986496	1.009227198	 0.940289184	 0.842624363
+.761598219	1.010059312	 0.934723671	 0.828625017
+.793331478	1.010929336	 0.928875035	 0.814032388
+.825064737	1.011837596	 0.922737076	 0.798848013
+.856797996	1.01278443	 0.916303251	 0.783073774
+.888531256	1.013770197	 0.909566661	 0.766711937
+.920264515	1.01479527	 0.902520043	 0.749765195
+.951997774	1.015860038	 0.895155752	 0.732236722
+.983731033	1.016964908	 0.887465751	 0.714130222
+.015464292	1.018110307	 0.879441592	 0.695449985
+.047197551	1.019296676	 0.8710744	 0.676200956
+.07893081	1.020524478	 0.862354861	 0.656388792
+.110664069	1.021794193	 0.853273198	 0.636019943
+.142397329	1.023106322	 0.843819155	 0.615101726
+.174130588	1.024461383	 0.833981977	 0.593642407
+.205863847	1.025859919	 0.82375039	 0.5716513
+.237597106	1.027302491	 0.813112573	 0.549138858
+.269330365	1.028789682	 0.802056142	 0.526116785
+.301063624	1.030322099	 0.790568118	 0.502598146
+.332796883	1.03190037	 0.778634906	 0.478597499
+.364530142	1.033525148	 0.766242261	 0.454131023
+.396263402	1.035197111	 0.753375263	 0.429216666
+.427996661	1.03691696	 0.740018284	 0.403874305
+.45972992	1.038685425	 0.726154954	 0.378125913
+.491463179	1.04050326	 0.711768126	 0.351995745
+.523196438	1.042371249	 0.696839839	 0.325510537
+.554929697	1.044290203	 0.681351278	 0.298699722
+.586662956	1.046260964	 0.665282732	 0.271595661
+.618396215	1.048284403	 0.64861355	 0.244233898
+.650129475	1.050361424	 0.631322093	 0.216653434
+.681862734	1.052492964	 0.613385687	 0.188897019
+.713595993	1.054679993	 0.594780567	 0.161011472
+.745329252	1.056923518	 0.575481822	 0.133048033
+.777062511	1.059224581	 0.555463336	 0.105062731
+.80879577	1.061584262	 0.534697725	 0.077116794
+.840529029	1.064003681	 0.513156272	 0.049277088
+.872262289	1.066484	 0.490808851	 0.021616595
+.903995548	1.069026422	 0.467623859	-0.005785076
+.935728807	1.071632194	 0.443568129	-0.032841123
+.967462066	1.074302612	 0.418606853	-0.059456951
+.999195325	1.077039017	 0.392703483	-0.085529513
+.030928584	1.079842802	 0.365819646	-0.110946599
+.062661843	1.082715411	 0.337915031	-0.135586067
+.094395102	1.085658345	 0.308947292	-0.159315006
+.126128362	1.08867316	 0.278871926	-0.181988834
+.157861621	1.091761474	 0.247642155	-0.203450318
+.18959488	1.094924965	 0.215208794	-0.223528513
+.221328139	1.098165381	 0.181520118	-0.242037616
+.253061398	1.101484536	 0.146521711	-0.258775724
+.284794657	1.104884319	 0.110156314	-0.273523491
+.316527916	1.108366697	 0.072363659	-0.286042681
+.348261175	1.111933717	 0.033080298	-0.296074601
+.379994435	1.115587515	-0.007760587	-0.303338425
+.411727694	1.11933032	-0.050229374	-0.307529379
+.443460953	1.12316446	-0.094400211	-0.308316806
+.475194212	1.127092372	-0.140351229	-0.305342096
+.506927471	1.131116609	-0.188164774	-0.298216493
+.53866073	1.135239852	-0.237927637	-0.286518776
+.570393989	1.139464924	-0.289731302	-0.269792846
+.602127248	1.143794808	-0.343672193	-0.247545241
+.633860508	1.148232666	-0.39985192	-0.219242641
+.665593767	1.152781872	-0.458377516	-0.184309461
+.697327026	1.157446048	-0.519361653	-0.142125667
+.729060285	1.162229122	-0.582922804	-0.092025093
+.760793544	1.167135405	-0.649185328	-0.033294642
+.792526803	1.172169712	-0.718279394	 0.034824895
+.824260062	1.17733755	-0.790340637	 0.113135186
+.855993321	1.18264542	-0.865509304	 0.202471616
+.887726581	1.188101346	-0.943928474	 0.303685139
+.91945984	1.193715839	-1.025740391	 0.417605887
+.951193099	1.199503802	-1.111078809	 0.54496891
+.982926358	1.205488688	-1.200051936	 0.686253524
+.014659617	1.2117128	-1.292700149	 0.841298052
+.046392876	1.21826791	-1.388871861	 1.008209416
+.078126135	1.225416475	-1.487741753	 1.179292479
+.109859394	1.234427405	-1.584566325	 1.314705175
+</pre>
+</div>
+  </td>
+  <td align="center">
+[[File:OurImprovedSummary2.png|400px|Chatterji's Figure 1]]
+  </td>
+  <td align="center">
+<table border="0" align="center" cellpadding="8">
+<tr>
+  <td align="center">Mode</td>
+  <td align="center"><math>\omega^2_\mathrm{Chatterji}</math></td>
+  <td align="center"><math>\sigma_c^2</math></td>
+</tr>
+<tr>
+  <td align="left">Fundamental</td>
+  <td align="center" bgcolor="yellow">0.2298579</td>
+  <td align="center">1.1492896</td>
+</tr>
+<tr>
+  <td align="left">1<sup>st</sup> Overtone</td>
+  <td align="center" bgcolor="yellow">1.4733124</td>
+  <td align="center">7.366562</td>
+</tr>
+<tr>
+  <td align="left">2<sup>nd</sup> Overtone</td>
+  <td align="center" bgcolor="yellow">3.3484654</td>
+  <td align="center">16.742327</td>
+</tr>
+</table>
+  </td>
+</tr>
+<tr>
+  <td align="left" colspan="3">
+The solid circular markers in the plot (center panel) show how the amplitude of the displacement function varies with radius <math>0 \le \eta < \pi</math> for three separate radial modes, according to the data provided in Table II of {{ Chatterji51 }}, which has been reproduced here in the ''scrollable'' left-hand panel.  In the plot, ''blue'' is the fundamental mode, ''red'' is the 1<sup>st</sup> overtone, ''green'' is the 2<sup>nd</sup> overtone.  The (square of the) eigenfrequency corresponding to each mode, according to Table I of {{ Chatterji51 }}, is provided in the column of the right-hand panel that is (highlighted in pink and) labeled <math>\omega^2_\mathrm{Chatterji}</math>; also listed are the corresponding values of <math>\sigma_c^2 = 3\gamma \omega^2_\mathrm{Chatterji}</math>.
+<br />&nbsp;<br />
+The smooth, solid curves in the middle-panel plot are ''not'' fits to Chatterji's data.  Rather, they result from our own, independent numerical integration of the relevant LAWE, assuming that Chatterji's published values of the (square of the) eigenfrequency are correct for all three modes.  In all three cases for the specified eigenfrequency, there is excellent agreement between our determination of the radial eigenfunction and the determination obtained by {{ Chatterji51 }}.
+  </td>
+</tr>
+</table>
+=====Pressure-Truncated n = 1 Polytrope=====
+Drawing from an [[SSC/Stability/NeutralMode#Part_2|accompanying discussion]], if the polytropic configuration is truncated by the pressure, <math>P_e</math>, of a hot, tenuous external medium, then the solution to the LAWE is subject to the outer boundary condition,
+<table border="0" cellpadding="5" align="center">
+<tr>
+   <td align="right">
+<math>
+-\frac{d\ln x}{d\ln\eta}
+</math>
+   </td>
+   <td align="center">
+<math>=</math>
+   </td>
+   <td align="left">
+<math>3</math> &nbsp; &nbsp; at &nbsp; &nbsp; <math>\eta = \tilde\eta</math>.
+   </td>
+</tr>
+</table>
+===Bipolytropic Envelope (Trial Simplification)===
+For the <math>n=1</math> envelope of a <math>(n_c, n_e) = (5, 1)</math> bipolytrope, the relevant LAWE is,
 <table border=0 cellpadding=2 align="center">
@@ Line 4,083: / Line 5,050: @@
 </tr>
 </table>
+=Try Again=
+Additional studies of radial oscillations in models that lie along the "51 Renormalized" sequences can be [[SSC/Structure/BiPolytropes/51RenormaizePart2|found here]].
+==Example BiPolytrope Sequence 0.3100==
+For the case of <math>(n_c, n_e) = (5, 1)</math> and <math>\mu_e/\mu_c = 0.3100</math>, we consider here the examination of models with three relatively significant values of the core/envelope interface:
+<ul>
+  <li>
+<math>(\xi_i, \bar\rho/\rho_c, q, \nu) \approx (2.06061, 1.1931E+02, 0.16296, 0.13754)</math>: Approximate location along the sequence of the model with the maximum fractional core radius.
+  </li>
+  <li>
+<math>(\xi_i, \bar\rho/\rho_c, q, \nu) \approx (2.69697, 3.0676E+02, 0.15819, 0.19161)</math>: Approximate location along the sequence of the onset of fundamental-mode instability.
+  </li>
+  <li>
+<math>(\xi_i, \bar\rho/\rho_c, q, \nu) \approx (9.0149598, 1.1664E+06, 0.075502255, 0.337217006)</math>: Exact location along the sequence of the model with the maximum fractional core mass.
+  </li>
+</ul>
 =See Also=

$q$	$\approx$	$\frac{x_{+} - x_{-}}{2 Δ_{η}}$
$\Rightarrow x_{-}$	$\approx$	$x_{+} - 2 q Δ_{η} .$

$x_{+} \cdot T E R M 1$	$=$	$(x_{+} - 2 q Δ_{η}) \cdot T E R M 2 + x_{i} \cdot T E R M 3$
$\Rightarrow x_{+} \cdot [T E R M 1 - T E R M 2]$	$=$	$x_{i} \cdot T E R M 3 - 2 q Δ_{η} \cdot T E R M 2 .$

$\frac{d P^{}}{d r^{}}$	$=$	$γ (ρ^{})^{γ - 1} {\exp [\frac{μ (γ - 1) s}{ℜ}]} \frac{d ρ^{}}{d r^{*}}$
$\Rightarrow \frac{1}{P_{c o r e}^{}} \cdot \frac{d P_{c o r e}^{}}{d r^{*}}$	$=$	$\frac{γ_{c}}{ρ_{c o r e}^{}} \cdot \frac{d ρ_{c o r e}^{}}{d r^{*}}$

SSC/Structure/BiPolytropes/Analytic51Renormalize: Difference between revisions

Latest revision as of 13:54, 20 November 2023

BiPolytrope with (nc, ne) = (5, 1)

Steps 2 & 3

Step 4: Throughout the core

Step 8: Throughout the envelope

Behavior of Central Density Along Equilibrium Sequence

Model Pairings

Attempt at Constructing Analytic Eigenfunction Expression

Background

Core

Envelope

Trial Displacement Function

2nd Trial

Numerical Integration Through Envelope

Setup

Continuous Form of LAWE

Discrete Form of LAWE

Pressure-Truncated n = 1 Polytrope

Review of Trial Analytic Eigenfunction

Determining Discrete Representation of Eigenfunction

Isolated n = 1 Polytrope

Pressure-Truncated n = 1 Polytrope

Bipolytropic Envelope (Trial Simplification)

Try m = 1 and m = 2

Try m = 3

Boundary Condition

Discrete Determination of Bipolytropic Envelope

Examine Pressure Gradient at the Interface

From Hydrostatic Balance

Pressure Gradient at Core Interface

Pressure Gradient at Envelope Interface

Pressure Gradient Summary

From Step-Function Behavior of Specific Entropy

Strategically Incorporate Step Function

Now Take Radial Derivative of Pressure

Try Again

Example BiPolytrope Sequence 0.3100

See Also

Navigation menu

Search

BiPolytrope with (n_c, n_e) = (5, 1)

2^nd Trial