Full text: The internal constitution of the stars

POLYTROPIC GAS SPHERES 
87 
his radius 
to (a) ten 
bhe circles 
les on the 
tre for the 
he actual 
■qual mass. 
Dolytropic 
3 material 
The inner 
ial energy 
icordingly 
de of using 
values) are 
3). 
Hence the negative potential energy of the whole star is 
n n I' M M r dM r 
Q = e l 0 r — (60-11) 
= iff rms 
Jo r 
M 2 i'R M 2 
- ie S + j 0 w *. 
by integration by parts. Or since GM r jr 2 = - dfi/dr 
Q = i<? Tf (60-12). 
Again since GM r = - r 2 d<f>/dr and dM r = 4tt r 2 pdr, 
(60-11) gives Q = - 477 I R r 3 p dr. 
Jo dr 
Writing p = \(j) n in accordance with (55-41) 
f<i> = o 
Q = -^1.L/ (W 
= f ^ n+1 by integration by parts 
3 r 
= I 4> • Tpr 2 dr (60-21) 
= ^Tlf^ dMr ( 60>22 ) 
= (60-3) 
by integration by parts. 
Comparing (60-12) and (60-3) 
Q,= iG — + ^ 1 O 
^ R + 6 
3 M 2 
Hence Q = - ¿r-p- (60-4). 
O — ??/ it 
We note for reference that 
Q = 3 I K P AjrrHr = 3 | Pdv (60-5), 
Jo J 
where dv is the element of volume. This follows from (60-21) and (55-42). 
Uniform density is given by n = 0 and (60-4) then gives the usual 
expression for a uniform sphere Q. = | GM 2 /R. For other distributions the 
numerical coefficient is greater, the mass being more concentrated to the 
centre. 61 
61. The result (60-4) shows that there must be some break-down in 
the analysis when n > 5. The failure occurs because such distributions 
/
	        
Waiting...

Note to user

Dear user,

In response to current developments in the web technology used by the Goobi viewer, the software no longer supports your browser.

Please use one of the following browsers to display this page correctly.

Thank you.