Solving Planetary Motion Homework: Showing v=sqrt(2G (M+m)/d)

AI Thread Summary
The discussion focuses on deriving the equation v=sqrt(2G (M+m)/d) for two masses accelerating towards each other due to gravity. The user is attempting to connect two equations involving gravitational force and kinetic energy but is encountering difficulties in simplifying the expressions correctly. They have reached an intermediate equation but suspect a calculation error in their derivation. The final goal is to express the speed of one mass relative to the other in terms of the given variables. Clarifying the mathematical steps and ensuring proper application of conservation laws is essential for reaching the correct solution.
Zeth
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Homework Statement



Two masses, m and M, are initially at rest at a great distance from each other. The gravitational force between them causes them to accelerate towards each other. Using conservation of energy and momentum, show that at any instant the speed of one of the particles relative to the other is:

v=sqrt(2G (M+m)/d)


where d is the distance between them at that instant.

The Attempt at a Solution



I have the solution sheet but am stuck as to what happens between:

0 = -GMm/d +1/2m v^2(1+m/M)

and

v^2 = 2GM^2/d(M+m)

where v is v_m, but that's not relevant again till the end of the question.

what I've gotten the top to reduce to is

v^2= 2GM[(m+M)/dm]

Am I missing some math trick here?
 
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The answer should be v=sqrt(2G (M+m)/d)*M, and you've made a calculation mistake somewhere...
 

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