Calculating Force of Gravitational Attraction: Mass M, m, Distance

AI Thread Summary
The gravitational force of attraction between two masses can be calculated using the formula Fg = GMm/r^2. In the given scenario, when mass M is tripled and the distance is doubled, the gravitational constant remains unchanged. By setting up a ratio of the forces, F2/F1, and substituting the known values, one can derive the new force F2. The approach simplifies to F2 = k * F1, where k accounts for the changes in mass and distance. This method allows for the calculation of the new gravitational force based on the modified parameters.
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Homework Statement



When the distance separating two masses, M and m, is 1.2 x 10^10 m, the gravitational force of attraction is 5.0 N. If the mass of M becomes 3M and the separation distance becomes
2.4 x 1010 m, what will be the force?


Homework Equations


Fg=MaMb/r^2


The Attempt at a Solution


since i have r and Fg (first part of question) i tried solving for the masses. but how do i solve for both when i need at least one to solve the other/??
 
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You're missing the gravitational constant in your equation. I suggest setting up a ratio between the two forces and see what happens.
 
huh? I am still kinda confused..
 
You know : F_1 = \frac{{GM_1 m_1 }}{{r_1 ^2 }} and that F_2 = \frac{{GM_2 m_2 }}{{r_2 ^2 }}.

What do you get when you divide the second equation by the first, that is: \frac{{F_2 }}{{F_1 }}.

You know:

\[<br /> \begin{array}{l}<br /> M_2 = 3M_1 \\ <br /> m_1 = m_2 \\ <br /> \end{array}<br /> \]<br />

along with the actual initial force, F_1. You can solve for the ratio of forces which will tell you what F_2 is.
 
or, use this EASIER way :

for the first condition, and the second condition, the gravitational constant is always the same.
G=G

You have known what the value of F is :
F=\frac{GMm}{r^2 }
and, the value of G is :
G=\frac{Fr^2 }{Mm}

you can make it like this :
G=G
\frac{Fr1^2 }{M1m1}=\frac{Fr2^2 }{M2m2}
substitute the variable ( like M2 to 3 Mi ) and you can eliminate the variable. At last, there will be an equation like F2 = k.F1
 
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