Stability of a BiPolytrope with an Isothermal Core

This analysis pulls largely from 📚 S. Yabushita (1975, MNRAS, Vol. 172, pp. 441 - 453); the focus is on bipolytropes having ${\displaystyle (n_c,n_e)=(\mathrm{\infty },\frac{3}{2})}$. In an accompanying discussion, we summarize the steps that Yabushita took — from 1968 and 1974, to 1975 — that led up to his discovery of an analytic description of the isothermal displacement function.

Equilibrium Structure

We will follow the accompanying formal recipe for building a bipolytropic model, using the step-by-step construction of Milne's (1930) configurations as a guide.

Step 1

The 📚 Yabushita (1975) bipolytrope has an isothermal core ${\displaystyle (n_c=\mathrm{\infty })}$ and an ${\displaystyle n_e=\frac{3}{2}}$ polytropic envelope.

Steps 2 & 3

Throughout the core, the properties of this bipolytrope can be expressed in terms of the Lane-Emden function, ${\displaystyle \psi (\chi )}$, which derives from a solution of the 2^nd-order ODE,

subject to the boundary conditions,

The solution, ${\displaystyle \psi (\xi )}$, extends to infinity, so the interface between the core and the envelope can be positioned anywhere within the range, ${\displaystyle 0<{\xi }_i<\mathrm{\infty }}$.

Step4: Throughout the core

After adopting the substitute notation, ${\displaystyle c_s^2\to K_1}$ and ${\displaystyle {\rho }_0\to {\lambda }_c}$, it is clear that these last four parameter-profile expressions are identical to the ones that appear, respectively, as equations (2.2), (2.1) and (2.3) of 📚 Yabushita (1975).

Step 5: Interface Conditions

This means that,

${\displaystyle \frac{{\rho }_e}{{\rho }_0}}$	${\displaystyle =}$	${\displaystyle \left(\frac{{\mu }_e}{{\mu }_c}\right)e^{-{\psi }_i}{\theta }_i^{-3/2};}$	(2.9)
${\displaystyle K_e\left[{\rho }_0\right(\frac{{\mu }_e}{{\mu }_c})e^{-{\psi }_i}{\theta }_i^{-3/2}{]}^{5/3}{\theta }_i^{5/2}}$	${\displaystyle =}$	${\displaystyle c_s^2{\rho }_0{e}^{-{\psi }_i}}$
${\displaystyle \Rightarrow \frac{K_e{\rho }_0^{2/3}}{c_s^2}}$	${\displaystyle =}$	${\displaystyle (\frac{{\mu }_e}{{\mu }_c}{)}^{-5/3}{e}^{+2{\psi }_i/3}}$
${\displaystyle \Rightarrow \frac{c_s^2}{K_e}}$	${\displaystyle =}$	${\displaystyle \left[\right(\frac{{\mu }_e}{{\mu }_c}{)}^{5/2}{\rho }_0{e}^{-{\psi }_i}{]}^{2/3};}$	(2.11)
${\displaystyle \frac{{\eta }_i}{{\xi }_i}}$	${\displaystyle =}$	${\displaystyle \left[\frac{c_s^2}{4\pi G{\rho }_0}{]}^{1/2}\right[\frac{4\pi G}{(5/2)K_e}{]}^{1/2}[{\rho }_e{]}^{1/6}}$
	${\displaystyle =}$	${\displaystyle \left(\frac{2}{5}{)}^{1/2}\right[\frac{c_s^2}{K_e}{]}^{1/2}\left[{\rho }_0\right(\frac{{\mu }_e}{{\mu }_c})e^{-{\psi }_i}{\theta }_i^{-3/2}{]}^{1/6}{\rho }_0^{-1/2}}$
	${\displaystyle =}$	${\displaystyle \left(\frac{2}{5}{)}^{1/2}\right[\left(\frac{{\mu }_e}{{\mu }_c}{)}^{5/2}{\rho }_0{e}^{-{\psi }_i}{]}^{1/3}\right[\left(\frac{{\mu }_e}{{\mu }_c}{)}^{1/6}{e}^{-{\psi }_i/6}{\theta }_i^{-1/4}\right]{\rho }_0^{-1/3}}$
	${\displaystyle =}$	${\displaystyle \left(\frac{2}{5}{)}^{1/2}\right(\frac{{\mu }_e}{{\mu }_c})e^{-{\psi }_i/2}{\theta }_i^{-1/4}.}$	(2.12)

And, finally,

See Also

• M. Gabriel & M. L. Roth (1974, A&A, Vol. 32, p. 309) … On the Secular Stability of Models with an Isothermal Core
• M. Gabriel & P. Ledoux (1967, Annales d'Astrophysique, Vol. 30, p. 975) … Sur la Stabilité Séculaire des Modeéles a Noyaux Isothermes
  

  In § 1 (p. 442) of 📚 Yabushita (1975) we find the following reference:   "A somewhat similar problem has been investigated by Gabriel & Ledoux (1967). Gaseous configurations with an isothermal core and polytropic envelope of index 3 were studied by 📚 Henrich & Chandrasekhar (1941) and by 📚 Schönberg & Chandrasekhar (1942). As is well known there is an upper limit (Schönberg-Chandrasekhar limit) to the mass of the core for the configurations to be in hydrostatic equilibria. Gabriel & Ledoux have investigated the stability of these configurations and have shown that secular stability is lost at the configuration that corresponds to the Schönberg-Chandrasekhar limit."