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Polytrope
Figure C.1:
Solutions of eq.(C.6) are plotted for indices of
or (the most extended one), or (the middle), and
or (the most compact one).
For gas extends infinitely and the solution has no zero-point.
|
If we choose the polytropic equation of stateC.1,
|
(C.1) |
the hydrostatic balance is expressed by
|
(C.2) |
where we used equations (4.1) and
(4.2).
A hydrostatic gaeous star composed with a polytropic gas is called polytrope.
Normalizing the density, pressure and radius as
we obtain a normalized equation as
|
(C.6) |
which is called Lane-Emden equation of index .
The boundary condition at the center of polytrope should be
at .
Solution of this equation is plotted for several in Figure C.1.
Mass of the polytrope is written down as
where represents the zero point of or the
surface radius normalized by .
For or
,
equation (C.9) reduces to
|
(C.10) |
Thus, the mass does not depend on the central density for
polytrope.
For or
, is written down as
|
(C.11) |
where and
.
Polytrope with gas, the mass-density relation
becomes
.
While, for of
, is written down as
|
(C.12) |
where and
.
Next: Magnetohydrostatic Configuration
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Kohji Tomisaka
2007-11-02