Main Sequence to Red Giant to Planetary Nebula

Part I:  Background & Objective

Part II:

Part III:

Part IV:

Succinct

Generic

may also be written as …

${\displaystyle 0}$

${\displaystyle =}$

${\displaystyle \frac{d^{2}x}{dr{*}^2}+\{4-(\frac{{\rho }^{*}}{P^{*}}\left)\frac{M_r^{*}}{(r^{*})}\right\}\frac{1}{r^{*}}\frac{dx}{dr*}+\left(\frac{{\rho }^{*}}{P^{*}}\right)\{\frac{2\pi {\sigma }_c^2}{3{\gamma }_{\mathrm{g}}}-(3-\frac{4}{{\gamma }_{\mathrm{g}}}\left)\frac{M_r^{*}}{(r^{*}{)}^3}\right\}x.}$

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

${\displaystyle 0}$

${\displaystyle =}$

${\displaystyle x^{″}+\frac{{\mathscr{H}}}{r^{*}}{x}^{\prime }+{𝒦}x,}$

where,

${\displaystyle x^{\prime }}$

${\displaystyle =}$

${\displaystyle \frac{dx}{d{r}^{*}}}$

and

${\displaystyle x^{″}}$

${\displaystyle =}$

${\displaystyle \frac{d^{2}x}{d(r^{*}{)}^2};}$

and,

and,

${\displaystyle {\mathscr{H}}}$

${\displaystyle \equiv }$

${\displaystyle \{4-(\frac{{\rho }^{*}}{P^{*}}\left)\frac{M_r^{*}}{(r^{*})}\right\}.}$

Specific Polytropes

In a separate discussion, we have shown that configurations with a polytropic equation of state exhibit a characteristic length scale that is given by the expression,

${\displaystyle a_n}$

${\displaystyle \equiv }$

${\displaystyle [\frac{(n+1)K}{4\pi G}\cdot {\rho }_c^{(1-n)/n}{]}^{1/2};}$

and, once the dimensionless polytropic temperature, ${\displaystyle \theta (\xi )}$, is known, the radial dependence of key physical variables is given by the expressions,

				if, as in a separate discussion, ${\displaystyle n=5}$ and ${\displaystyle \theta =(1+{\xi }^2/3{)}^{-1/2}}$ …
${\displaystyle r_0}$	${\displaystyle =}$	${\displaystyle a_n\xi ,}$		${\displaystyle r_0}$	${\displaystyle =}$	${\displaystyle [\frac{K}{G}\cdot {\rho }_c^{-4/5}{]}^{1/2}(\frac{3}{2\pi }{)}^{1/2}\xi ,}$
${\displaystyle {\rho }_0}$	${\displaystyle =}$	${\displaystyle {\rho }_c{\theta }^n,}$		${\displaystyle {\rho }_0}$	${\displaystyle =}$	${\displaystyle {\rho }_c{\theta }^5,}$
${\displaystyle P_0}$	${\displaystyle =}$	${\displaystyle K{\rho }_0^{(n+1)/n}=K{\rho }_c^{(n+1)/n}{\theta }^{n+1},}$		${\displaystyle P_0}$	${\displaystyle =}$	${\displaystyle K{\rho }_c^{6/5}{\theta }^6,}$
${\displaystyle M(r_0)}$	${\displaystyle =}$	${\displaystyle 4\pi {\rho }_c{a}_n^3(-{\xi }^2\frac{d\theta }{d\xi })={\rho }_c^{(3-n)/(2n)}\left[\frac{(n+1{)}^3{K}^3}{4\pi G^3}{]}^{1/2}\right(-{\xi }^2\frac{d\theta }{d\xi }),}$		${\displaystyle g_0}$	${\displaystyle =}$	${\displaystyle \frac{GM(r_0)}{r_0^2}=\frac{G}{r_0^2}\left[4\pi a_n^3{\rho }_c\right(-{\xi }^2\frac{d\theta }{d\xi }\left)\right],}$
${\displaystyle g_0}$	${\displaystyle =}$	${\displaystyle \frac{GM(r_0)}{r_0^2}=\frac{G}{r_0^2}\left[4\pi a_n^3{\rho }_c\right(-{\xi }^2\frac{d\theta }{d\xi }\left)\right],}$		${\displaystyle g_0}$	${\displaystyle =}$	${\displaystyle \frac{GM(r_0)}{r_0^2}=\frac{G}{r_0^2}\left[4\pi a_n^3{\rho }_c\right(-{\xi }^2\frac{d\theta }{d\xi }\left)\right],}$

Notice that, ${\displaystyle \frac{g_0{\rho }_0{r}_0}{P_0}}$ ${\displaystyle =}$ ${\displaystyle \frac{G}{a_n^2{\xi }^2}\left[4\pi a_n^3{\rho }_c\right(-{\xi }^2\frac{d\theta }{d\xi }\left)\right]\cdot {\rho }_c{\theta }^n\cdot a_n\xi \cdot [K{\rho }_c^{(n+1)/n}{\theta }^{n+1}{]}^{-1}}$   ${\displaystyle =}$ ${\displaystyle \frac{4\pi G}{K}\left[{\rho }_c^{1-1/n}\right](-\xi \frac{d\theta }{d\xi })\cdot {\theta }^{-1}\cdot a_n^2}$   ${\displaystyle =}$ ${\displaystyle (n+1)(-\frac{\xi }{\theta }\cdot \frac{d\theta }{d\xi });}$ ${\displaystyle \frac{{\rho }_0{r}_0^2}{P_0}}$ ${\displaystyle =}$ ${\displaystyle {\rho }_c{\theta }^n\cdot (a_n\xi {)}^2\cdot [K{\rho }_c^{(n+1)/n}{\theta }^{n+1}{]}^{-1}}$   ${\displaystyle =}$ ${\displaystyle K^{-1}{\rho }_c^{-1/n}\cdot a_n^2\cdot \frac{{\xi }^2}{\theta }}$   ${\displaystyle =}$ ${\displaystyle \left[\frac{(n+1)}{4\pi G{\rho }_c}\right]\cdot \frac{{\xi }^2}{\theta }.}$

As a result, for polytropes we can write,

${\displaystyle 0}$	${\displaystyle =}$	${\displaystyle \frac{d^{2}x}{d{r}_0^2}+[4-(\frac{g_0{\rho }_0{r}_0}{P_0}\left)\right]\frac{1}{r_0}\cdot \frac{dx}{d{r}_0}+\left(\frac{{\rho }_0{r}_0^2}{{\gamma }_{\mathrm{g}}{P}_0}\right)[{\omega }^2+(4-3{\gamma }_{\mathrm{g}})\frac{g_0}{r_0}]\frac{x}{r_0^2}}$
	${\displaystyle =}$	${\displaystyle \frac{d^{2}x}{d{r}_0^2}+[4-(\frac{g_0{\rho }_0{r}_0}{P_0}\left)\right]\frac{1}{r_0}\cdot \frac{dx}{d{r}_0}+\left[\frac{{\omega }^2}{{\gamma }_{\mathrm{g}}}\right(\frac{{\rho }_0{r}_0^2}{P_0})-(3-\frac{4}{{\gamma }_{\mathrm{g}}}\left)\right(\frac{g_0{\rho }_0{r}_0}{P_0}\left)\right]\frac{x}{r_0^2}}$
	${\displaystyle =}$	${\displaystyle \frac{d^{2}x}{d{r}_0^2}+[4-(n+1)Q]\frac{1}{r_0}\cdot \frac{dx}{d{r}_0}+(n+1)\left[\frac{{\omega }^2}{{\gamma }_{\mathrm{g}}}\right[\frac{1}{4\pi G{\rho }_c}]\cdot \frac{{\xi }^2}{\theta }-(3-\frac{4}{{\gamma }_{\mathrm{g}}}\left)Q\right]\frac{x}{r_0^2}.}$

Finally, multiplying through by ${\displaystyle a_n^2}$ — which everywhere converts ${\displaystyle r_0}$ to ${\displaystyle \xi }$ — gives, what we will refer to as the,

BiPolytrope

Let's stick with the dimensional ${\displaystyle (r_0)}$ version and set ${\displaystyle {\omega }^2=0}$, that is,

${\displaystyle 0}$

${\displaystyle =}$

${\displaystyle \frac{d^{2}x}{d{r}_0^2}+[4-(n+1)Q]\frac{1}{r_0}\cdot \frac{dx}{d{r}_0}-[(n+1)\alpha Q]\frac{x}{r_0^2}.}$

Core (n = 5)

For the ${\displaystyle n=5}$ core, we know that ${\displaystyle \theta =(1+{\xi }^2/3{)}^{-1/2}}$. Hence,

${\displaystyle Q\equiv -\frac{d\ln \theta }{d\ln \xi }}$

${\displaystyle =}$

${\displaystyle .}$

Envelope (n = 1)

Related Discussions

• Instability Onset Overview
• Analytic ${\displaystyle (n_c,n_e)=(5,1)}$
  • Part 1
  • Part 2

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