Question

A launching pad with a spaceship is moving along a circular orbit of the moon, whose radius $R$ is triple that of the moon $R_m$. The ship leaves the launching pad with a relative velocity equal to the launching pad's initial orbital velocity $V_0$ and the launching pad then falls to the moon. If the angle $\theta =co{s}^{-1}\frac{n}{\sqrt{10}}$ with the horizontal is the angle at which the launching pad crashes into the surface and its mass is twice that of the spaceship, then the value of $n$ is

Answer 1

Let $V_r$ be the relative velocity of the spaceship w.r.t the launching pad. Thus,
$V_r=V_0$
$\Rightarrow V_s-V_l=V_0$ -----(i) (where $V_s$ and $V_l$ are the velocities of the spaceship and the launching pad after splitting)

Using conservation of momentum along the tagential direction we can say

$(m+2m)V_0=m{V}_s+2m{V}_l$ -----(ii)


Using (i) and (ii) we get
$V_l=\frac{2}{3}{V}_o$ and
$V_s=\frac{5}{3}{V}_o$

Let $v$ and $\theta$ be the velocity and the angle at which the launching pad strikes the surface of the moon.

On applying conservation of total energy on the launching pad of mass $2m$,

$K_i+U_i=K_f+U_f$
$\frac{1}{2}\left(2m\right){\left(\frac{2}{3}{v}_0\right)}^2+\left[\frac{-GM\left(2m\right)}{3R_m}\right]=\frac{1}{2}\left(2m\right)v^2+\left[\frac{-GM\left(2m\right)}{R_m}\right]$ --- (iii)

We know orbital velocity $v_0=\sqrt{\frac{GM}{R_0}}=\sqrt{\frac{GM}{3R_m}}$

Substituting in equation (iii), we get

$v=\sqrt{\frac{40GM}{27R_m}}$



By applying conservation of angular momentum, we can say

$\left(2m\right)\left(\frac{2}{3}{V}_0\right)\left(3R_m\right)=\left(2m\right)\left(v\right)\left(R_m\right)\left(sin\right(90-\theta \left)\right)$
$⟹\theta =co{s}^{-1}(\frac{3}{\sqrt{10}}$)
$\therefore$ value of $n$ is 3