=BiPolytrope with n_c = 5 and n_e = 1=

Equations (A2) from {{ EFC98 }} present the same relations but adopt the following notations:<font color="red" size="+2"><b>*</b></font>

   <td align="left"><math>\biggl[ \frac{K_c^3}{G^3\rho_0^{2/5}} \biggr]\biggl( \frac{2\cdot 3}{\pi} \biggr)^{1 / 2}  

 

<tr>

  <td align="right">&nbsp;</td>

  <td align="center"><math>=</math></td>

  <td align="left">

 

  <td align="right">&nbsp;</td>

  <td align="center"><math>=</math></td>

  <td align="left">

 

  <td align="right">&nbsp;</td>

  <td align="center"><math>=</math></td>

<math>

-A \cdot

 

 

 

 

 

<math>\frac{P}{K_c\rho_0^{6/5}}</math>

 

 

 

 

 

 

 

 

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, n_e) = (5, 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. 

 

<b>Table 1:  Properties of <math>(n_c, n_3) = (5, 1)</math> BiPolytrope Having Various Interface Locations, <math>\xi_i</math></b><br>

 

<table border="1" cellpadding="5" width="80%">

<tr>

  <td align="center">

<math>\xi_i</math>

  </td>

  <td align="center">

[[File:Bipolytrope51Boundaries02.png|500px|Examples]]<br />

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  </td>

\frac{1}{\eta_i} -

\biggl(\frac{\mu_e}{\mu_c} \biggr) \frac{3}{2\eta_i } \biggl\{ 1 \pm 

\sqrt{1 - \biggl[ \biggl(\frac{\mu_e}{\mu_c} \biggr)^{-1} \frac{2 \eta_i }{3}\biggr]^2  }

\biggr\} \, .

 

[As of 28 April 2013] For the interface locations <math>\xi_i = 0.5, 1.0,\mathrm{and}~3.0</math>, Table 2 provides profiles for three values of the molecular weight ratio:  <math>\mu_e/\mu_c = 1.0, 1/2,\mathrm{and}~1/4</math>.  In all nine graphs, blue diamonds trace the structure of the <math>n_c=5</math> core; the core extends to a radius, <math>r^*_\mathrm{core}</math>, that is independent of molecular weight ratio but varies in direct proportion to the choice of <math>\xi_i</math>.  Specifically, as tabulated in the fourth row of Table 1, <math>r^*_\mathrm{core} = 0.34549, ~0.69099, \mathrm{and} ~2.07297</math> for, respectively, <math>\xi_i = 0.5,~1,~\mathrm{and}~3</math>.  Notice that, while the pressure profile and mass profile are continuous at the interface for all choices of the molecular weight ratio, the density profile exhibits a discontinuous jump that is in direct proportion to the chosen value of <math>\mu_e/\mu_c</math>. 

 

Throughout the <math>n_e = 1</math> envelope, the profile of all physical variables varies with the choice of the molecular weight ratio.  In the Table 2 graphs, red squares trace the envelope profile for <math>\mu_e/\mu_c = 1.0</math>; green triangles trace the envelope profile for <math>\mu_e/\mu_c = 1/2</math>; and purple crosses trace the envelope profile for <math>\mu_e/\mu_c = 1/4</math>.  The surface of the bipolytropic configuration is defined by the (normalized) radius, <math>R^*</math>, at which the envelope density and pressure drop to zero; the values tabulated in row 16 of Table 1 &#8212; <math>1.35550, ~1.62766, ~\mathrm{and} ~3.35697</math> for, respectively, <math>\xi_i = 0.5,~1,~\mathrm{and}~3</math> &#8212; correspond to a molecular weight ratio of unity and, hence also, to the envelope profiles traced by red squares in the Table 2 graphs.  As the molecular weight ratio is decreased from unity to <math>1/2</math> and, then, <math>1/4</math> for a given choice of <math>\xi_i</math>, the (normalized) radius of the bipolytrope increases roughly in inverse proportion to <math>\mu_e/\mu_c</math> as suggested by the formula for <math>R^*</math> shown in Table 1.  This proportional relation is not exact, however, because the parameter <math>\eta_s</math>, which also appears in the formula for <math>R^*</math>, contains an implicit dependence on the chosen value of the molecular weight ratio through the parameter <math>\eta_i</math>.

 

For a given choice of the interface parameter, <math>\xi_i</math>, the (normalized) mass that is contained in the core is independent of the choice of the molecular weight ratio.  However, the (normalized) total mass, <math>M_\mathrm{tot}^*</math>, varies significantly with the choice of <math>\mu_e/\mu_c</math>; as suggested by the expression provided in row 17 of Table 1, the variation is in rough proportion to <math>(\mu_e/\mu_c)^{-2}</math> but, as with <math>R^*</math>, this proportional relation is not exact because the parameters <math>\eta_s</math> and <math>A</math> which also appear in the formula for <math>M_\mathrm{tot}^*</math> harbor an implicit dependence on the molecular weight ratio.

 

 

 

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 &#8212; or at least to some value, <math>\xi_i \gg 1</math>.  Figure 1 shows how the fractional core mass, <math>\nu \equiv M_\mathrm{core}/M_\mathrm{tot}</math>, varies with the fractional core radius, <math>q \equiv r_\mathrm{core}/R</math>, along sequences having six different values of <math>\mu_e/\mu_c</math>, as detailed in the figure caption.  The natural expectation is that an increase in <math>\xi_i</math> along a given sequence will correspond to an increase in the relative size &#8212; both the radius and the mass &#8212; of the core. This expectation is realized along the sequences marked by blue diamonds (<math>\mu_e/\mu_c = 1</math>) and by red squares (<math>\mu_e/\mu_c = </math>&frac12;).  But the behavior is different along the other four illustrated sequences.  For sufficiently large <math>\xi_i</math>, the relative radius of the core begins to decrease; then, as <math>\xi_i</math> is pushed to even larger values, eventually the relative core mass begins to decrease.  Additional properties of these equilibrium sequences are discussed in [[SSC/FreeEnergy/PolytropesEmbedded#Behavior_of_Equilibrium_Sequence|an accompanying chapter]].

<table border="0" cellpadding="5" width="85%">

 

  <td align="center" colspan="2" bgcolor="white">

[[Image:PlotSequencesBest02.png|500px|center]]

 

'''Figure 1:'''  Analytically determined plot of fractional core mass (<math>\nu</math>) versus fractional core radius (<math>q</math>) for <math>(n_c, n_e) = (5, 1)</math> bipolytrope model sequences having six different values of <math>\mu_e/\mu_c</math>: 1 (blue diamonds), &frac12; (red squares), 0.345 (dark purple crosses), &#8531; (pink triangles), 0.309 (light green dashes),  and &frac14; (purple asterisks).  Along each of the model sequences, points marked by solid-colored circles correspond to models whose interface parameter, <math>\xi_i</math>, has one of three values:  0.5 (green circles), 1 (dark blue circles), or 3 (orange circles); the images linked to Table 2 provide plots of the density, pressure and mass profiles for nine of these identified models.

</table>

 

The variation of <math>\nu</math> with <math>q</math> for a seventh analytically determined model sequence &#8212; one for which <math>\mu_e/\mu_c = 1/5</math> &#8212; is mapped out by a string of blue diamond symbols in the left-hand side of Figure 2. It behaves in an analogous fashion to the <math>\mu_e/\mu_c = </math>&frac14; (purple asterisks) sequence displayed in Figure 1.  It also quantitatively, as well as qualitatively, resembles the sequence that was numerically constructed by {{ SC42full }} for models with an isothermal core (<math>n_c = \infty</math>) and an <math>n_e=3/2</math> envelope; Fig. 1 from their paper has been reproduced here on the right-hand side of Figure 2.

 

 

 

 

 

 

 

 

 

Before carrying out the desired differentiations, we will find it useful to rewrite the relevant expressions in terms of the parameters,

\ell_i \equiv \frac{\xi_i}{\sqrt{3}} \, ;

</math>

m_3 \equiv 3 \biggl( \frac{\mu_e}{\mu_c} \biggr) \, .

 

We obtain,

 

<div align="center">

<table border="0" cellpadding="5">

<math>\eta_i</math>

<math>=</math>

 

<math>=</math>

\frac{1}{m_3\ell_i} [ 1 + (1-m_3)\ell_i^2]  ~~~ \Rightarrow ~~~  

   </td>

<math>=</math>

 

 

<math>=</math>

\frac{1}{m_3^2} \biggl[ 1 + (1-m_3)^2 \ell_i^2 \biggr]^{1/2}

\biggl\{  \biggl(\frac{\pi}{2} + \tan^{-1} \Lambda_i \biggr) + m_3 \ell_i (1 + \ell_i^2)^{-1} \biggr\} \, .

   </td>

<math>

=

</math>

(\ell_i^3) (1 + \ell_i^2)^{-1/2} \biggl[ \ell_i + (1+\ell_i^2) \biggl(\frac{\pi}{2} + \tan^{-1} \biggl(\frac{1}{\ell_i}\biggr) \biggr) \biggr]^{-1} \, ,</math>

and the maximum value of <math>\nu</math> along this sequence arises when <math>\ell_i \rightarrow \infty</math>, in which case,

\nu

   </td>

\ell_i^2  \biggl[ \ell_i + (1+\ell_i^2) \biggl(\frac{\pi}{2} \biggr) \biggr]^{-1}

<math>=</math>

\frac{\partial \tan^{-1}\Lambda_i}{\partial \ln \ell_i} = 

\frac{[(1-m_3)\ell_i^2 - 1 ] }{m_3\ell_i (1 + \Lambda_i^2)}

= \frac{m_3 \ell_i [(1-m_3)\ell_i^2 - 1 ]}{(1 + \ell_i^2) [ 1 + (1-m_3)^2 \ell_i^2]} \, .

 

 

   </td>

m_3\ell_i \biggl\{[(1-m_3)\ell_i^2 - 1 ] -(\ell_i^2 + 2)[ 1 + (1-m_3)^2 \ell_i^2 ] + (1-m_3)^2 \ell_i^2 (1+\ell_i^2) \biggr\} \, ,

<math>=</math>

\underbrace{m_3 \ell_i [(1-m_3)\ell_i^4 - (m_3^2 - m_3 +2)\ell_i^2 - 3]}_{\mathrm{RHS}} \, .

</math>