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</table>
</table>
and,
and,
<div align="center">
<table border="0" cellpadding="5" align="center">
<math>~\mathcal{K} \equiv ~\biggl(\frac{\rho^*}{ P^* } \biggr)\biggl[ \biggl(\frac{\sigma_c^2}{\gamma_\mathrm{g}}\biggr)\frac{2\pi }{3}
- \biggl(3 - \frac{4}{\gamma_\mathrm{g}}\biggr) \frac{M_r^*}{(r^*)^3} \biggr] \, .</math>
</div>


<tr>
  <td align="right"><math>\mathcal{K}</math></td>
  <td align="center"><math>=</math></td>
  <td align="left">
<math>
\biggl(\frac{\rho^*}{ P^* } \biggr)\biggl[ \biggl(\frac{\sigma_c^2}{\gamma_\mathrm{g}}\biggr)\frac{2\pi }{3}
- \biggl(3 - \frac{4}{\gamma_\mathrm{g}}\biggr) \frac{M_r^*}{(r^*)^3} \biggr]
=
\biggl(\frac{\sigma_c^2}{\gamma_\mathrm{g}}\biggr)\frac{2\pi }{3}\biggl(\frac{\rho^*}{ P^* } \biggr)
- \biggl(3 - \frac{4}{\gamma_\mathrm{g}}\biggr) \frac{\rho^*}{ P^* }\cdot \frac{M_r^*}{(r^*)} \cdot \frac{1}{(r^*)^2}
</math>
  </td>
</tr>


<tr>
  <td align="right">&nbsp;</td>
  <td align="center"><math>=</math></td>
  <td align="left">
<math>
\biggl(\frac{\sigma_c^2}{\gamma_\mathrm{g}}\biggr)\frac{2\pi }{3}\biggl[\biggl( \frac{\mu_e}{\mu_c} \biggr) \theta^{-1}_i \phi^{-1}\biggr]
- 2\biggl(3 - \frac{4}{\gamma_\mathrm{g}}\biggr) \biggl(-\frac{d\ln\phi}{d\ln\eta}\biggr)
\biggl[ \biggl( \frac{\mu_e}{\mu_c} \biggr)^{-1} \theta^{-2}_i (2\pi)^{-1/2}\eta\biggr]^{-2}
</math>
  </td>
</tr>
<tr>
  <td align="right">&nbsp;</td>
  <td align="center"><math>=</math></td>
  <td align="left">
<math>
\biggl(\frac{\sigma_c^2}{\gamma_\mathrm{g}}\biggr)\frac{2\pi }{3}\biggl[\biggl( \frac{\mu_e}{\mu_c} \biggr) \theta^{-1}_i \phi^{-1}\biggr]
- 2\biggl(3 - \frac{4}{\gamma_\mathrm{g}}\biggr) 
\biggl[ \biggl( \frac{\mu_e}{\mu_c} \biggr)^{2} \theta^{4}_i (2\pi)\eta^{-2}\biggr]\biggl(-\frac{d\ln\phi}{d\ln\eta}\biggr) \, .
</math>
  </td>
</tr>
</table>


<table border="1" cellpadding="8" width="80%" align="center"><tr><td align="left">
<table border="1" cellpadding="8" width="80%" align="center"><tr><td align="left">

Revision as of 18:27, 10 January 2026

Main Sequence to Red Giant to Planetary Nebula (Part 2)


Part I:  Background & Objective

 


Part II: 

 


Part III: 

 


Part IV: 

 

Foundation

In an accompanying discussion, we derived the so-called,

Adiabatic Wave (or Radial Pulsation) Equation

d2xdr02+[4r0(g0ρ0P0)]dxdr0+(ρ0γgP0)[ω2+(43γg)g0r0]x=0

whose solution gives eigenfunctions that describe various radial modes of oscillation in spherically symmetric, self-gravitating fluid configurations.

Introducing the dimensionless frequency-squared, σc23ω2/(2πGρc), we can rewrite this LAWE as,

0

=

d2xdr02+[4(g0r0ρ0r02P0)]1r0dxdr0+(ρ0r02P0)[2πGρcσc23γg(34γg)g0r0]xr02,

where, as a reminder, g0GM(r0)/r02. Now, for our (nc,ne)=(5,1) bipolytrope, we have found it useful to adopt the following four dimensionless variables:

ρ*

ρ0ρc

;    

r*

r0[Kc1/2/(G1/2ρc2/5)]

P*

P0Kcρc6/5

;    

Mr*

Mr[Kc3/2/(G3/2ρc1/5)]

This means that,

g0r0=GM(r0)r03

=

GMr*[Kc3/2G3/2ρc1/5]r*3[Kc3/2G3/2ρc6/5]=[Gρc]Mr*r*3;

ρ0r02P0

=

ρ*ρc(r*)2[KcG1ρc4/5](P*)1[Kc1ρc6/5]=[G1ρc1]ρ*(r*)2(P*)1;

g0r0ρ0r02P0

=

[Gρc]Mr*r*3[G1ρc1]ρ*(r*)2(P*)1=Mr*ρ*P*r*.

Making these substitutions, the LAWE can be rewritten as,

0

=

d2xdr02+[4Mr*ρ*P*r*]1r0dxdr0+1Gρc[ρ*(r*)2P*][2πGρcσc23γg(34γg)GρcMr*(r*)3]xr02;

then, multiplying through by [KG1ρc4/5] allows us to everywhere switch from (r0)2 to (r*)2, namely,

0

=

d2xd(r*)2+[4Mr*ρ*P*r*]1r*dxd(r*)+[ρ*(r*)2P*][2πσc23γg(34γg)Mr*(r*)3]x(r*)2.

In shorthand, we can rewrite this equation in the form,

0

=

x+r*x+𝒦x,

where,

x

=

dxdr*

      and      

x

=

d2xd(r*)2;

and,

𝒦(ρ*P*)[(σc2γg)2π3(34γg)Mr*(r*)3];

and,

{4(ρ*P*)Mr*(r*)}.

Specific Case of (nc, ne) = (5,1)

Drawing from our "Table 2" profiles, let's evaluate and 𝒦 for the two separate regions of bipolytrope model.

The nc = 5 Core

r*=(32π)1/2ξ

ρ*P*

=

(1+ξ23)5/2(1+ξ23)6/2=(1+ξ23)1/2

M*r*

=

(23π)1/2[ξ3(1+ξ23)3/2](2π3)1/2ξ1=2ξ2(1+ξ23)3/2

=

42ξ2(1+ξ23)3/2(1+ξ23)1/2=42ξ2(1+ξ23)1.

Also,

𝒦

=

(1+ξ23)1/2{(σc2γg)2π3(34γg)2ξ2(1+ξ23)3/2(2π3)ξ2}=2π3(1+ξ23)1/2{(σc2γg)2(34γg)(1+ξ23)3/2}

Hence, the LAWE becomes,

0

=

[2π3]d2xdξ2+[]2π3ξ1dxdξ+2π3(1+ξ23)1/2{(σc2γg)2(34γg)(1+ξ23)3/2}x.

Multiplying through by 3ξ2/(2π) gives,

0

=

ξ2d2xdξ2+[4ξ2ξ3(1+ξ23)1]dxdξ+ξ2(1+ξ23)1/2{(σc2γg)2(34γg)(1+ξ23)3/2}x.

Let's compare this with the equivalent expression presented separately, namely,

Polytropic LAWE (linear adiabatic wave equation)

0=d2xdξ2+[4(n+1)Q]1ξdxdξ+(n+1)[(σc26γg)ξ2θαQ]xξ2

where:    Q(ξ)dlnθdlnξ,    σc23ω22πGρc,     and,     α(34γg)

The primary E-type solution for n = 5 polytropes states that,

θn=5

=

[1+ξ23]1/2.

Q=ξθdθdξ

=

ξ[1+ξ23]1/2ddξ[1+ξ23]1/2

 

=

+ξ[1+ξ23]1/2{ξ3[1+ξ23]3/2}

 

=

ξ23[1+ξ23]1.

Hence, the LAWE may be written as,

0

=

d2xdξ2+[46Q]1ξdxdξ+6[(σc26γg)ξ2θ(34γg)Q]xξ2

 

=

d2xdξ2+{42ξ2[1+ξ23]1}1ξdxdξ+{(σc2γg)ξ2[1+ξ23]1/22ξ2(34γg)[1+ξ23]1}xξ2

 

=

d2xdξ2+{42ξ2[1+ξ23]1}1ξdxdξ+{(σc2γg)[1+ξ23]1/22(34γg)[1+ξ23]1}x

Versus above,

0

=

ξ2d2xdξ2+[4ξ2ξ3(1+ξ23)1]dxdξ+ξ2(1+ξ23)1/2{(σc2γg)2(34γg)(1+ξ23)3/2}x.

If we set γg=6/5 and we set σc2=0, this becomes,

0

=

ξ2d2xdξ2+[4ξ2ξ3(1+ξ23)1]dxdξ+23ξ2(1+ξ23)1x

Next, try the solution, x=(1ξ2/15)dx/dξ=2ξ/15 and d2x/dx2=2/15:

LAWE

=

215ξ2[4ξ2ξ3(1+ξ23)1]2ξ15+23ξ2(1+ξ23)1[1ξ2/15]

15(1+ξ23)  LAWE

=

2ξ2(1+ξ23)[60ξ(1+ξ23)30ξ3]2ξ15+10ξ2[1ξ2/15]

 

=

2ξ22ξ43[60ξ210ξ4]215+1015[15ξ2ξ4]

 

=

2ξ22ξ43[4ξ223ξ4]2+[10ξ223ξ4]

 

=

2ξ22ξ438ξ2+43ξ4+[10ξ223ξ4]

 

=

0.

The ne = 1 Envelope

Throughout the envelope we have,

r*

=

(μeμc)1θi2(2π)1/2η

ρ*P*

=

[(μeμc)θi5ϕ][θi6ϕ2]=(μeμc)θi1ϕ(η)1;

Mr*r*

=

(μeμc)2θi1(2π)1/2(η2dϕdη)[(μeμc)1θi2(2π)1/2η]1=2(μeμc)1θiη(η2dϕdη).

Hence,

{4(ρ*P*)Mr*(r*)}=4[(μeμc)θi1ϕ1][2(μeμc)1θiη(η2dϕdη)]=42(dlnϕdlnη);

and,

𝒦 =

(ρ*P*)[(σc2γg)2π3(34γg)Mr*(r*)3]=(σc2γg)2π3(ρ*P*)(34γg)ρ*P*Mr*(r*)1(r*)2

  =

(σc2γg)2π3[(μeμc)θi1ϕ1]2(34γg)(dlnϕdlnη)[(μeμc)1θi2(2π)1/2η]2

  =

(σc2γg)2π3[(μeμc)θi1ϕ1]2(34γg)[(μeμc)2θi4(2π)η2](dlnϕdlnη).

Let's compare this with the equivalent expression presented separately, namely,

Polytropic LAWE (linear adiabatic wave equation)

0=d2xdξ2+[4(n+1)Q]1ξdxdξ+(n+1)[(σc26γg)ξ2θαQ]xξ2

where:    Q(ξ)dlnθdlnξ,    σc23ω22πGρc,     and,     α(34γg)

The equilibrium, off-center equilibrium solution for n = 1 polytropes states that,

ϕn=1

=

Aηsin(Bη);

dϕdη

=

Addη{η1sin(Bη)}

 

=

A{η2sin(Bη)+η1cos(Bη)};

Q=ηϕdϕdη

=

η[Aηsin(Bη)]1A{η2sin(Bη)+η1cos(Bη)}

 

=

η[ηsin(Bη)]{η2sin(Bη)+η1cos(Bη)}

 

=

[1+ηcot(Bη)]

Hence, the LAWE may be written as,

0

=

d2xdη2+{42[1+ηcot(Bη)]}1ηdxdη+2{(σc26γg)η2ϕ(34γg)[1+ηcot(Bη)]}xη2

First Try

x

=

ηmdxdη=mηm1       and     d2xdη2=m(m1)ηm2,

in which case,

LAWE

=

m(m1)ηm2+{42[1+ηcot(Bη)]}1η[mηm1]+2{(σc26γg)η2ϕ(34γg)[1+ηcot(Bη)]}ηm2

ηm+2×LAWE

=

m(m+1)m{42[1+ηcot(Bη)]}+2{(σc26γg)η2ϕ(34γg)[1+ηcot(Bη)]}.

Now set σc2=0 and set γg=2:

ηm+2×LAWE

=

m(m+1)m{42[1+ηcot(Bη)]}2{[1+ηcot(Bη)]}

 

=

m(m+1)4m+2m[1+ηcot(Bη)]2[1+ηcot(Bη)]

We see that the complexity of the LAWE reduces substantially if we set m=+1; specifically, this choice gives,

[ηm+2×LAWE]m1

=

2.

Close, but no cigar!

Second Try

Next, let's set σc2=0 but let's leave γg unspecified:

ηm+2×LAWE

=

m(m+1)m{42[1+ηcot(Bη)]}2{(34γg)[1+ηcot(Bη)]}

 

=

m(m+1)4m+2m[1+ηcot(Bη)]2(34γg)[1+ηcot(Bη)]

 

=

m(m3)+{2m2(34γg)}[1+ηcot(Bη)].

The first term goes to zero if we set m=3; then, in order for the second term to go to zero, we need …

0

=

{62(34γg)}

γg

=

.

This means that the envelope is incompressible.

Third Try

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