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Revision as of 02:56, 28 April 2013
BiPolytrope with <math>n_c = 5</math> and <math>n_e=1</math>
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Here we construct a bipolytrope in which the core has an <math>n_c=5</math> polytropic index and the envelope has an <math>n_c=1</math> polytropic index. This system is particularly interesting because the entire structure can be described by closed-form, analytic expressions. As far as I have been able to determine, this analytic structural model has not previously been published in a refereed, archival journal (author: Joel E. Tohline, March 30, 2013). In deriving the properties of this model, we will follow the general solution steps for constructing a bipolytrope that we have outlined elsewhere.
Steps 2 & 3
Based on the discussion presented elsewhere of the structure of an isolated <math>n=5</math> polytrope, the core of this bipolytrope will have the following properties:
<math> \theta(\xi) = \biggl[ 1 + \frac{1}{3}\xi^2 \biggr]^{-1/2} ~~~~\Rightarrow ~~~~ \theta_i = \biggl[ 1 + \frac{1}{3}\xi_i^2 \biggr]^{-1/2} ; </math>
<math> \frac{d\theta}{d\xi} = - \frac{\xi}{3}\biggl[ 1 + \frac{1}{3}\xi^2 \biggr]^{-3/2} ~~~~\Rightarrow ~~~~ \biggl(\frac{d\theta}{d\xi}\biggr)_i = - \frac{\xi_i}{3}\biggl[ 1 + \frac{1}{3}\xi_i^2 \biggr]^{-3/2} \, . </math>
The first zero of the function <math>\theta(\xi)</math> and, hence, the surface of the corresponding isolated <math>n=5</math> polytrope is located at <math>\xi_s = \infty</math>. Hence, the interface between the core and the envelope can be positioned anywhere within the range, <math>0 < \xi_i < \infty</math>.
Step 4: Throughout the core (<math>0 \le \xi \le \xi_i</math>)
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Specify: <math>K_c</math> and <math>\rho_0 ~\Rightarrow</math> |
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<math>\rho</math> |
<math>=</math> |
<math>\rho_0 \theta^{n_c}</math> |
<math>=</math> |
<math>\rho_0 \biggl( 1 + \frac{1}{3}\xi^2 \biggr)^{-5/2}</math> |
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<math>P</math> |
<math>=</math> |
<math>K_c \rho_0^{1+1/n_c} \theta^{n_c + 1}</math> |
<math>=</math> |
<math>K_c \rho_0^{6/5} \biggl( 1 + \frac{1}{3}\xi^2 \biggr)^{-3}</math> |
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<math>r</math> |
<math>=</math> |
<math>\biggl[ \frac{(n_c + 1)K_c}{4\pi G} \biggr]^{1/2} \rho_0^{(1-n_c)/(2n_c)} \xi</math> |
<math>=</math> |
<math>\biggl[ \frac{K_c}{G\rho_0^{4/5}} \biggr]^{1/2} \biggl(\frac{3}{2\pi}\biggr)^{1/2} \xi</math> |
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<math>M_r</math> |
<math>=</math> |
<math>4\pi \biggl[ \frac{(n_c + 1)K_c}{4\pi G} \biggr]^{3/2} \rho_0^{(3-n_c)/(2n_c)} \biggl(-\xi^2 \frac{d\theta}{d\xi} \biggr)</math> |
<math>=</math> |
<math>\biggl[ \frac{K_c^3}{G^3 \rho_0^{2/5} } \biggr]^{1/2} \biggl( \frac{2\cdot 3}{\pi } \biggr)^{1/2} \biggl[ \xi^3 \biggl( 1 + \frac{1}{3}\xi^2 \biggr)^{-3/2} \biggr]</math> |
Step 5: Interface Conditions
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Setting <math>n_c=5</math>, <math>n_e=1</math>, and <math>\phi_i = 1 ~~~~\Rightarrow</math> |
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<math>\frac{\rho_e}{\rho_0}</math> |
<math>=</math> |
<math>\biggl( \frac{\mu_e}{\mu_c} \biggr) \theta^{n_c}_i \phi_i^{-n_e}</math> |
<math>=</math> |
<math>\biggl( \frac{\mu_e}{\mu_c} \biggr) \theta^{5}_i </math> |
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<math>\biggl( \frac{K_e}{K_c} \biggr) </math> |
<math>=</math> |
<math>\rho_0^{1/n_c - 1/n_e}\biggl( \frac{\mu_e}{\mu_c} \biggr)^{-(1+1/n_e)} \theta^{1 - n_c/n_e}_i</math> |
<math>=</math> |
<math>\rho_0^{-4/5}\biggl( \frac{\mu_e}{\mu_c} \biggr)^{-2} \theta^{-4}_i</math> |
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<math>\frac{\eta_i}{\xi_i}</math> |
<math>=</math> |
<math>\biggl[ \frac{n_c + 1}{n_e+1} \biggr]^{1/2} \biggl( \frac{\mu_e}{\mu_c}\biggr) \theta_i^{(n_c-1)/2} \phi_i^{(1-n_e)/2}</math> |
<math>=</math> |
<math>3^{1/2} \biggl( \frac{\mu_e}{\mu_c}\biggr) \theta_i^{2}</math> |
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<math>\biggl( \frac{d\phi}{d\eta} \biggr)_i</math> |
<math>=</math> |
<math>\biggl[ \frac{n_c + 1}{n_e + 1} \biggr]^{1/2} \theta_i^{- (n_c + 1)/2} \phi_i^{(n_e+1)/2} \biggl( \frac{d\theta}{d\xi} \biggr)_i</math> |
<math>=</math> |
<math>3^{1/2} \theta_i^{- 3} \biggl( \frac{d\theta}{d\xi} \biggr)_i</math> |
Step 6: Envelope Solution
Adopting equation (8) of Beech (1988), the most general solution to the <math>n=1</math> Lane-Emden equation can be written in the form,
<math> \phi = A \biggl[ \frac{\sin(\eta - B)}{\eta} \biggr] \, , </math>
where <math>A</math> and <math>B</math> are constants. The first derivative of this function is,
<math> \frac{d\phi}{d\eta} = \frac{A}{\eta^2} \biggl[ \eta\cos(\eta-B) - \sin(\eta-B) \biggr] \, . </math>
From Step 5, above, we know the value of the function, <math>\phi</math> and its first derivative at the interface; specifically,
<math> \phi_i = 1~~~~\mathrm{and} ~~~~\biggl( \frac{d\phi}{d\eta}\biggr)_i =3^{1/2} \theta_i^{- 3} \biggl( \frac{d\theta}{d\xi} \biggr)_i~~~~ \mathrm{at}~~~~\eta_i =3^{1/2} \xi_i \biggl( \frac{\mu_e}{\mu_c}\biggr) \theta_i^{2}</math>
From this information we can determine the constants <math>A</math> and <math>B</math>; specifically,
<math> \eta_i - B = \tan^{-1}(\Lambda_i^{-1}) = \frac{\pi}{2}- \tan^{-1}(\Lambda_i) \, , </math>
<math> A = \frac{\phi_i \eta_i}{\sin(\eta_i - B)} = \phi_i \eta_i (1 + \Lambda_i^2)^{1/2} \, , </math>
where,
<math> \Lambda_i = \frac{1}{\eta_i} + \frac{1}{\phi_i} \biggl(\frac{d\phi}{d\eta}\biggr)_i \, . </math>
Step 7
The surface will be defined by the location, <math>\eta_s</math>, at which the function <math>\phi(\eta)</math> first goes to zero, that is,
<math> \eta_s = \pi + B = \frac{\pi}{2} + \eta_i + \tan^{-1}(\Lambda_i) \, . </math>
Step 8: Throughout the envelope (<math>\eta_i \le \eta \le \eta_s</math>)
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Knowing: <math>K_e/K_c</math> and <math>\rho_e/\rho_0</math> from Step 5 <math>\Rightarrow</math> |
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<math>\rho</math> |
<math>=</math> |
<math>\rho_e \phi^{n_e}</math> |
<math>=</math> |
<math>\rho_0 \biggl(\frac{\rho_e}{\rho_0}\biggr) \phi</math> |
<math>=</math> |
<math>\rho_0 \biggl( \frac{\mu_e}{\mu_c} \biggr) \theta^{5}_i \phi</math> |
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<math>P</math> |
<math>=</math> |
<math>K_e \rho_e^{1+1/n_e} \phi^{n_e + 1}</math> |
<math>=</math> |
<math>K_c \rho_0^{6/5} \biggl(\frac{K_e \rho_0^{4/5}}{K_c}\biggr) \biggl(\frac{\rho_e}{\rho_0}\biggr)^{2} \phi^{2}</math> |
<math>=</math> |
<math>K_c \rho_0^{6/5} \theta^{6}_i \phi^{2}</math> |
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<math>r</math> |
<math>=</math> |
<math>\biggl[ \frac{(n_e + 1)K_e}{4\pi G} \biggr]^{1/2} \rho_e^{(1-n_e)/(2n_e)} \eta</math> |
<math>=</math> |
<math>\biggl[ \frac{K_c}{G \rho_0^{4/5}} \biggr]^{1/2} \biggl( \frac{K_e \rho_0^{4/5}}{K_c} \biggr)^{1/2} (2\pi)^{-1/2}\eta</math> |
<math>=</math> |
<math>\biggl[ \frac{K_c}{G \rho_0^{4/5}} \biggr]^{1/2} \biggl( \frac{\mu_e}{\mu_c} \biggr)^{-1} \theta^{-2}_i (2\pi)^{-1/2}\eta</math> |
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<math>M_r</math> |
<math>=</math> |
<math>4\pi \biggl[ \frac{(n_e + 1)K_e}{4\pi G} \biggr]^{3/2} \rho_e^{(3-n_e)/(2n_e)} \biggl(-\eta^2 \frac{d\phi}{d\eta} \biggr)</math> |
<math>=</math> |
<math>\biggl[ \frac{K_c^3}{G^3 \rho_0^{2/5}} \biggr]^{1/2} \biggl( \frac{K_e \rho_0^{4/5}}{K_c} \biggr)^{3/2} \biggl(\frac{\rho_e}{\rho_0}\biggr) \biggl( \frac{2}{\pi} \biggr)^{1/2} \biggl(-\eta^2 \frac{d\phi}{d\eta} \biggr)</math> |
<math>=</math> |
<math>\biggl[ \frac{K_c^3}{G^3 \rho_0^{2/5}} \biggr]^{1/2} \biggl( \frac{\mu_e}{\mu_c} \biggr)^{-2} \theta^{-1}_i \biggl( \frac{2}{\pi} \biggr)^{1/2} \biggl(-\eta^2 \frac{d\phi}{d\eta} \biggr)</math> |
Examples
Normalization
The dimensionless variables used in Tables 1 & 2 are defined as follows:
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<math>\rho^*</math> |
<math>\equiv</math> |
<math>\frac{\rho}{\rho_0}</math> |
; |
<math>r^*</math> |
<math>\equiv</math> |
<math>\frac{r}{[K_c^{1/2}/(G^{1/2}\rho_0^{2/5})]}</math> |
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<math>P^*</math> |
<math>\equiv</math> |
<math>\frac{P}{K_c\rho_0^{6/5}}</math> |
; |
<math>M_r^*</math> |
<math>\equiv</math> |
<math>\frac{M_r}{[K_c^{3/2}/(G^{3/2}\rho_0^{1/5})]}</math> |
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<math>H^*</math> |
<math>\equiv</math> |
<math>\frac{H}{K_c\rho_0^{1/5}}</math> |
. |
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Parameter Values
The <math>2^\mathrm{nd}</math> column of Table 1 catalogues the analytic expressions that define various parameters and physical properties (as identified, respectively, in column 1) of the <math>n_c=5</math>, <math>n_e=1</math> bipolytrope. We have evaluated these expressions for various choices of the dimensionless interface radius, <math>\xi_i</math>, and have tabulated the results in the last few columns of the table. The tabulated values have been derived assuming <math>\mu_e/\mu_c = 1</math>, that is, assuming that the core and the envelope have the same mean molecular weights. The tabulated values of various parameters can be adjusted to correspond to other choices of this ratio by multiplying by the appropriate scaling coefficient as shown in column 1 of Table 1. For example, if the interface is positioned at <math>\xi_i = 0.5</math> but <math>\mu_e/\mu_c = 0.2</math>, then <math>\eta_i= 4.0</math> instead of <math>0.8</math>.
Table 1: Properties of <math>n_c=5</math>, <math>n_e=1</math>, BiPolytrope Having Various Interface Locations, <math>\xi_i</math>
File:BiPolytropeParametersV01.xml
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Parameter |
<math>\xi_i</math> |
0.5 |
1.0 |
3.0 |
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<math>\theta_i</math> |
<math>\biggl( 1+\frac{1}{3}\xi_i^2 \biggr)^{-1/2}</math> |
0.96077 |
0.86603 |
0.50000 |
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<math>-\biggl(\frac{d\theta_i}{d\xi}\biggr)_i</math> |
<math>\frac{1}{3} \xi_i \biggl( 1+\frac{1}{3}\xi_i^2 \biggr)^{-3/2}</math> |
0.14781 |
0.21651 |
0.12500 |
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<math>r^*_\mathrm{core} \equiv r^*_i</math> |
<math>\biggl( \frac{3}{2\pi} \biggr)^{1/2} \xi_i</math> |
0.34549 |
0.69099 |
2.07297 |
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<math>\rho^*_i \biggr|_c = \biggl( \frac{\mu_e}{\mu_c} \biggr)^{-1} \rho^*_i \biggr|_e</math> |
<math>\biggl( 1+\frac{1}{3}\xi_i^2 \biggr)^{-5/2}</math> |
0.81864 |
0.48714 |
0.03125 |
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<math>P^*_i</math> |
<math>\biggl( 1+\frac{1}{3}\xi_i^2 \biggr)^{-3}</math> |
0.78653 |
0.42188 |
0.01563 |
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<math>H^*_i \biggr|_c = \frac{n_c+1}{n_e+1} \biggl( \frac{\mu_e}{\mu_c} \biggr) H^*_i \biggr|_e</math> |
<math>6 \biggl( 1+\frac{1}{3}\xi_i^2 \biggr)^{-1/2}</math> |
5.76461 |
5.19615 |
3.00000 |
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<math>M^*_\mathrm{core}</math> |
<math>\biggl( \frac{6}{\pi}\biggr)^{1/2} (\xi_i \theta_i)^3</math> |
0.15320 |
0.89762 |
4.66417 |
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<math>\biggl( \frac{\mu_e}{\mu_c} \biggr)^{-1}\eta_i</math> |
<math>\sqrt{3} ~\theta_i^2 \xi_i</math> |
0.79941 |
1.29904 |
1.29904 |
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<math>-\biggl( \frac{d\phi}{d\eta} \biggr)_i</math> |
<math>\sqrt{3} ~\theta_i^{-3} \biggl( - \frac{d\theta}{d\xi} \biggr)_i = \frac{\xi_i}{\sqrt{3}}</math> |
0.28868 |
0.57735 |
1.73205 |
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<math>\Lambda_i</math> |
<math>\frac{1}{\eta_i} + \biggl( \frac{d\phi}{d\eta} \biggr)_i</math> |
0.96225 |
0.19245 |
-0.96225 |
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<math>A</math> |
<math>\eta_i (1 + \Lambda_i^2)^{1/2}</math> |
1.10940 |
1.32288 |
1.80278 |
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<math>B</math> |
<math>\eta_i - \frac{\pi}{2} + \tan^{-1}( \Lambda_i)</math> |
- 0.00523 |
-0.08163 |
-1.03792 |
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<math>\eta_s</math> |
<math>\pi + B</math> |
3.13637 |
3.05996 |
2.10367 |
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<math>- \biggl( \frac{d\phi}{d\eta} \biggr)_s</math> |
<math>\frac{A}{\eta_s}</math> |
0.35372 |
0.43232 |
0.85697 |
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<math>\biggl( \frac{\mu_e}{\mu_c} \biggr) \cdot \biggl[ R^* \equiv r^*_s \biggr]</math> |
<math>\frac{\eta_s}{\sqrt{2\pi} ~\theta_i^2}</math> |
1.35550 |
1.62766 |
3.35697 |
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<math>\biggl( \frac{\mu_e}{\mu_c} \biggr)^2 M^*_\mathrm{tot}</math> |
<math>\biggl(\frac{2}{\pi}\biggr)^{1/2} \theta_i^{-1} \biggl( -\eta^2 \frac{d\phi}{d\eta} \biggr)_s = \biggl(\frac{2}{\pi}\biggr)^{1/2} \frac{A\eta_s}{\theta_i}</math> |
2.88959 |
3.72945 |
6.05187 |
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<math>\biggl(\frac{\mu_e}{\mu_c}\biggr)^{-2} \cdot \biggl[ \nu \equiv \frac{M_\mathrm{core}}{M_\mathrm{tot}} \biggr]</math> |
<math>\sqrt{3} ~\biggl( \frac{\xi_i^3 \theta_i^4}{A\eta_s} \biggr)</math> |
0.05302 |
0.24068 |
0.77070 |
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<math>\biggl(\frac{\mu_e}{\mu_c}\biggr)^{-1} \cdot \biggl[ q \equiv \frac{r_\mathrm{core}}{R} \biggr]</math> |
<math>\sqrt{3}~\biggl[\frac{\xi_i \theta_i^2}{\eta_s}\biggr]</math> |
0.25488 |
0.42453 |
0.61751 |
 |
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Profile
Once the values of the key set of parameters have been determined as illustrated in Table 1, the radial profile of various physical variables can be determined throughout the bipolytrope as detailed in step #4 and step #8, above. Table 2 summarizes the mathematical expressions that define the profile throughout the core (column 2) and throughout the envelope (column 3) of the normalized mass density, <math>\rho^*(r^*)</math>, the normalized gas pressure, <math>P^*(r^*)</math>, and the normalized mass interior to <math>r^*</math>, <math>M_r^*(r^*)</math>. For all profiles, the relevant normalized radial coordinate is <math>r^*</math>, as defined in the <math>2^\mathrm{nd}</math> row of Table 2. Graphical illustrations of these resulting profiles can be viewed by clicking on the thumbnail images posted in the last few columns of Table 2.
Table 2: Radial Profile of Various Physical Variables
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Variable |
Throughout the Core |
Throughout the Envelope† |
Plotted Profiles |
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<math>\xi_i = 0.5</math> |
<math>\xi_i = 1.0</math> |
<math>\xi_i = 3.0</math> |
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<math>r^*</math> |
<math>\biggl( \frac{3}{2\pi} \biggr)^{1/2} \xi</math> |
<math>\biggl( \frac{\mu_e}{\mu_c} \biggr)^{-1} \theta^{-2}_i (2\pi)^{-1/2}\eta</math> |
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<math>\rho^*</math> |
<math>\biggl( 1 + \frac{1}{3}\xi^2 \biggr)^{-5/2}</math> |
<math>\biggl( \frac{\mu_e}{\mu_c} \biggr) \theta^{5}_i \phi(\eta)</math> |
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<math>P^*</math> |
<math>\biggl( 1 + \frac{1}{3}\xi^2 \biggr)^{-3}</math> |
<math>\theta^{6}_i [\phi(\eta)]^{2}</math> |
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<math>M_r^*</math> |
<math>\biggl( \frac{2\cdot 3}{\pi } \biggr)^{1/2} \biggl[ \xi^3 \biggl( 1 + \frac{1}{3}\xi^2 \biggr)^{-3/2} \biggr]</math> |
<math>\biggl( \frac{\mu_e}{\mu_c} \biggr)^{-2} \theta^{-1}_i \biggl( \frac{2}{\pi} \biggr)^{1/2} \biggl(-\eta^2 \frac{d\phi}{d\eta} \biggr)</math> |
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†In order to obtain the various envelope profiles, it is necessary to evaluate <math>\phi(\eta)</math> and its first derivative using the information presented in Step 6, above. |
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[As of 20 April 2013] For the interface location <math>\xi_i = 0.5</math>, Table 2 provides profiles for two values of the molecular weight ratio: <math>\mu_e/\mu_c = 1.0</math> and <math>\mu_e/\mu_c = 1/2</math>. Notice that, while the pressure profile and mass profile are continuous at the interface for both choices of the molecular weight ratio, the density profile exhibits a discontinuous jump when <math>\mu_e/\mu_c \ne 1.0</math>. Notice as well that, while the (normalized) radial coordinate of the core-envelope interface is independent of the choice of <math>\mu_e/\mu_c</math>, the (normalized) radius of the bipolytrope, <math>R^*</math>, and the normalized total mass, <math>M_\mathrm{tot}^*</math>, vary with the choice of <math>\mu_e/\mu_c</math> in accordance with the scalings presented above in Table 1. For example, when <math>\mu_e/\mu_c</math> is changed from unity to <math>1/2</math>, the radius of the configuration doubles and the total mass quadruples.
Model Sequences
For a given choice of <math>\mu_e/\mu_c</math> a physically relevant sequence of models can be constructed by steadily increasing the value of <math>\xi_i</math> from zero to infinity — or at least to some value, <math>\xi_i \gg 1</math>. The blue curve shown on the left-hand side of Figure 1 presents one such model sequence, generated for the choice <math>\mu_e/\mu_c = 0.2</math>. The curve shows how the fractional core mass, <math>\nu \equiv M_\mathrm{core}/M_\mathrm{tot}</math>, varies in relation to the fractional core radius, <math>q \equiv r^*_\mathrm{core}/R^*_\mathrm{tot}</math>; the analytic expressions for these two ratios are presented in the last two rows of Table 1.
The expectation is that an increase in <math>\xi_i</math> along the sequence will correspond to an increase in the size — both the radius and the mass — of the core. This expectation is realized
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Figure 1: Fractional mass versus fractional radius along the equilibrium sequence |
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Analytic BiPolytrope with <math>n_c=5</math>, <math>n_e = 1</math>, and <math>\mu_e/\mu_c = 0.2</math> |
Edited excerpt from Schönberg & Chandrasekhar (1942) |
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Plot of fractional core mass (<math>\nu</math>) versus fractional core radius (<math>q</math>) for the analytic bipolytrope having <math>\mu_e/\mu_c = 0.2</math>. The behavior of this analytically defined model sequence closely resembles the behavior of the numerically constructed isothermal core model presented by Schönberg & Chandrasekhar (1942). |
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© 2014 - 2021 by Joel E. Tohline |