According to the Third Kepler’s Law of Planetary motion “The square of the orbital period of a planet is proportional to the cube of the semi-major axis (size) of its orbit”.
In other words, this law states a relation between the orbital period [tex]T[/tex] of a body (moon, planet, satellite) orbiting a greater body in space with the size [tex]R[/tex] of its orbit.
This Law is originally expressed as follows (in the case of planet X and assuming we have a circular orbit):
[tex]T^{2}=\frac{4\pi^{2}}{GM}R^{3}[/tex] (1)
Where:
[tex]G[/tex] is the Gravitational Constant
[tex]M=1.9(10)^{27}kg[/tex] is the mass of planet X
[tex]R[/tex] is the radius of the orbit of the satellite around planet X
If we want to find the period, we have to express equation (1) as written below and substitute all the values:
[tex]T=2\pi\sqrt{\frac{R^{3}}{GM}}[/tex] (2)
Now, we are asked to find the period when tha mass of the planet is [tex]\frac{1}{4}M[/tex]. In order to do this, we have to rewrite equation (2) with this new value:
[tex]T=2\pi\sqrt{\frac{R^{3}}{G(\frac{1}{4}M)}}[/tex] (3)
Solving:
[tex]T=4\pi\sqrt{\frac{R^{3}}{G(\frac{1}{4}M)}}[/tex] (4)
On the other hand, if we multiply both sides of equation (2) by 2, we have:
[tex]2T=4\pi\sqrt{\frac{R^{3}}{GM}}[/tex] (5)
As we can see, (5) is equal to (4). This means the orbital period is twice the orignal period.
Hence, the answer is:
If Planet X had one-fourth as much mass, the orbital period of this satellite in an orbit of the same radius would be 2T.
