How Long Does It Take for a Comet With Zero Angular Momentum to Reach the Sun?

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a) The comet released from rest at a distance rmax from the sun ( angular momentum =0 ). How long comet takes to reach the sun ? (take sun`s radius to be zero )
b) Assuming the comet can somehow pass freely through the sun describe its overal motion and find its period ?


I can't really think how to solve this problem , what I know it that since angular mom is zero, c=0 ( C= l^2/gama*reduced mass ,Gama=GMsMc)
so so if c=o c=rmax*(1-e) e=1 therefore Energy E=0 ( accually E=0 doesn't make sense eather since it has a PE = -Gmsmc/rmax ) so that is not a bonded orbit but parabolic orbit, But How can I use these to find the time ? the hint is use the technique t= integral dx/xdot where we find xdot from the Energy ( KE=mxdot/2=E-U(x) ) but I still don't understand how to use this since my understanding ( e=0 so E=0 )

please help, I would appreciate if anyone help. I still don't feel as if I completeley understood this subject but I have to turn the homework tomorrow :((
 
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Well, since the angular momentum is zero, this is just a one-dimensional forced motion problem. You know the force as a function of distance, so set this equal to m d2r/dt2 and solve the resulting ODE.
 
the answer is different than what I find

thanks for your reply but when I set the equation, the 't' I find is
t= r max^2/2GMs but the answer is t= (pi/2*root(2GMs))*(r max)^3/2 more like Kepler`s IIIth law. Do you have any suggestion for this one and the the b) ? ?

thanks again
 
How did you arrive at your expression for the time?

Also, don't you expect the answer to resemble Kepler - since Kepler's Law relate to elliptical orbits and the particular orbit here is also an ellipse in the limit that the semiminor radius goes to zero (degenerate)?
 
I actually expect that but I am confused a little. I understand that since angular mom=0 c=0 so c=rmax(1-e) e=1 a (semimajor)=rmax/2 and c=rmin(1+e) for c to be equal to zero rmin ( semiminor must go to zero. Right ? but But I still can not find the right answer :(( ( t= (pi/2*root(2GMs))*(r max)^3/2 )
 
The formula 1.1\sqrt{\frac{a^3}{GM}} provides an impressively accurate estimation.

b. The comet would be become trapped in the Sun's Schwartchild radius, as the Sun would be a black hole if it's radius were 0. But since it said "pass freely through", I'm just guessing, but wouldn't it distance itself from the Sun by the height it was dropped, except 180 degrees away, then fall back to the Sun, and continue this indefinately, like a pendulum?
 
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The value of H equals ## 10^{3}## in natural units, According to : https://en.wikipedia.org/wiki/Natural_units, ## t \sim 10^{-21} sec = 10^{21} Hz ##, and since ## \text{GeV} \sim 10^{24} \text{Hz } ##, ## GeV \sim 10^{24} \times 10^{-21} = 10^3 ## in natural units. So is this conversion correct? Also in the above formula, can I convert H to that natural units , since it’s a constant, while keeping k in Hz ?
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