Newtons Laws EX 37

The two masses are placed on the x-axis as shown in the diagram below:

Now, we want to place the small particle of mass ${\displaystyle m}$ so that it is in equilibrium. There are only two forces acting on this particle: the gravitational force exerted by the mass ${\displaystyle 4M}$, ${\displaystyle F_{G_{4}}}$, and the gravitational force exerted by the mass ${\displaystyle M}$, ${\displaystyle F_{G}}$. Both of these forces are attractive. In other words, ${\displaystyle F_{G_{4}}}$ points towards the mass ${\displaystyle 4M}$ and ${\displaystyle F_{G}}$ points towards the mass ${\displaystyle M}$. Since we want ${\displaystyle m}$ to be in equilibrium we are looking for a place where these two forces have equal magnitudes and opposite directions.

Let's think where we could place the particle ${\displaystyle m}$ so that the forces have equal magnitudes and opposite directions. We can think of three regions in the space around the masses ${\displaystyle 4M}$ and ${\displaystyle M}$ (see the diagram below): x-axis, the gray region above and greenish region below the x-axis.

As you can see from the sketches above, the placement of ${\displaystyle m}$ in either the blue or greenish region results in forces which do not have opposite directions. Therefore we should look for a placement along the x-axis. Try to visualize which way the two forces will act if the particle ${\displaystyle m}$ is (i) to the left of ${\displaystyle 4M}$, (ii) in between the two masses, and (iii) to the right of mass ${\displaystyle M}$. I think that you will reach the conclusion that the particle ${\displaystyle m}$ should be located between ${\displaystyle 4M}$ and ${\displaystyle M}$ at some distance ${\displaystyle x}$ from ${\displaystyle 4M}$. Its distance from ${\displaystyle M}$ will then be (1 - x).

Now we can use the Newton Law of gravitation and write the equation stating that the magnitudes of the two forces are equal:

${\displaystyle F_{G_{4}}=F_{G}}$

${\displaystyle {G(4M)m \over x^{2}}={G(M)m \over (1-x)^{2}}}$

Cancelling ${\displaystyle G}$, ${\displaystyle M}$ and ${\displaystyle m}$, we get:

${\displaystyle {4 \over x^{2}}={1 \over (1-x)^{2}}}$

Take (positive) square roots:

${\displaystyle {2 \over x}={1 \over 1-x}}$

Cross multiply and solve for ${\displaystyle x}$ to find ${\displaystyle x=2/3}$ m.