Answer:
v= 4055.08m/s
Explanation:
This is a problem that must be addressed through the laws of classical mechanics that concern Potential Gravitational Energy.
We know for definition that,
[tex]U = \frac{GMm}{r}[/tex]
We must find the highest point and the lowest point to identify the change in energy, so
Point a)
The problem tells us that an object is dropped at a distance of h = 1.15134R over the earth.
That is to say that the energy of that object is equal to,
[tex]U_1=-\frac{(6.6738 * 10^{-11})(5.98 * 10^{24})(94.2)}{(1.15134)(6.38*10^6)}[/tex]
[tex]U_2= - 5.1180*10^9J[/tex]
Point B )
We now use the average radius distance from the earth.
[tex]U_2=-\frac{(6.6738 * 10^{-11})(5.98 * 10^{24})(94.2)}{(6.38*10^6)}[/tex]
[tex]U_2= -5.8925*10^9J[/tex]
Then,
[tex]\Delta U = U_2 - U_1 = -5.1180*10^9J - ( -5.8925*10^9J)[/tex]
[tex]\Delta U = 774.5*10^6[/tex]
By the law of conservation of energy we know that,
[tex]\Delta U = \frac{1}{2}mv^2[/tex]
clearing v,
[tex]v= \sqrt{2 \Delta U/m}[/tex]
[tex]v= \sqrt{2*774.5*10^6 /94.2}[/tex]
[tex]v= 4055.08m/s[/tex]
Therefore the speed of the object when it strikes the Earth’s surface is 4055.08m/s
