Keplers Third Law: Showing T^2 ∝ R^3

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The discussion focuses on deriving Kepler's Third Law, T^2 ∝ R^3, by equating gravitational force and centripetal force acting on a planet in circular orbit. Participants clarify that the gravitational force formula, F = GMm/r^2, can be set equal to the centripetal force expression, F = (m4π^2 r)/T^2. By canceling mass and rearranging the equation, they demonstrate that 4π^2 R^3 = GMT^2, leading to the conclusion that R^3 is proportional to T^2. Confusion arises around energy equations, but the main focus remains on the correct application of force equations to derive the relationship. The discussion effectively illustrates the mathematical foundation of Kepler's Third Law.
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Homework Statement


By considering the centripetal force which acts on a planet in a cirlar orbit, show that T^2\proptoR^3, where T is the time taken for one orbitaround the Sun and R is the radius of the orbit.


Homework Equations


Fc=GMm/r^2
1/2Mv^2=GMm/r^2


The Attempt at a Solution


I showed that F\propto1/d^2 but then could not incorporate R^3 into the equation...
 
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Well, you made it clear that you know that the gravitational force IS the centripetal force on the planet, and you have the expression for the gravitational force. What is the formula for the centripetal force on an object? Equate these two formulas.
 
skiing4free said:
1/2Mv^2=GMm/r^2

This equation isn't even dimensionally correct,
and KE <> PE.
 
davieddy said:
This equation isn't even dimensionally correct,
and KE <> PE.

Thats exactly what i showed, Ek=Epg. (<>, that doesn't make sense?)
 
skiing4free said:
Thats exactly what i showed, Ek=Epg. (<>, that doesn't make sense?)

<> means NOT equal to.
Anyway potential energy is -GMm/r.

Even if you had erroneously said KE= PE you could have deduced
T^2 proportional to r^3.
 
as was previously said just equate the expressions for the gravitational force and the centripetal force GMm/r^2=m(v^2)/r and play with it a bit then use some basic formulas for circular motion for angular velocity and time period and you will get the expression for T and R with some constants in it. Where did you find this : 1/2Mv^2=GMm/r^2 ?
 
Sorry i got really confused with the energy equations this is what i meant to write;

F=(m4\pi^2 r)/T^2

F=GMm/r^2

so

(m4\pi^2 r)/T^2=GMm/r^2

m cancels, left with 4\pi^2 r^3=GMT^2

\Rightarrow r^3\proptoT^2
 

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