Answer:
New height reached = (M²/m²)h
Step-by-step explanation:
As M>>m you can see the final height is very large compared to the initial height, which agrees the experiment.
Theory
1.The principle of conservation of Mechanical energy
In a system which the only forces are acting are associating with potential energy, the sum of kinetic energy and potential energies is constant.
2. The law of conservation of linear momentum
The sum of linear momentum of a closed system under no external unbalance force remains the same.
⇒
m ≪ M suggest you the mass of small ball is negligible compared to the mass of super ball.
1.Put the principle of conservation of Mechanical energy ( or principle of conservation of energy),
(K.E. of two balls at height h)+(P.E. of two balls at height h) =
(K.E. of two balls just before bounce)+(P.E. of two balls just before bounce)
We consider gravitational potential energy at ground level as 0.
We get,
0 + (M+m)gh =
(M+m)
u = velocity of the composite body.
u =
-------------------(1)
2.As two balls collide superball get highly compressed and transfer all its momentum to the ball.
Now apply the law of conservation of linear momentum , it is given that collisions with the superball are elastic,
(linear momentum of super ball + small ball before collision) = (linear momentum of super ball after collision) + (linear momentum of small ball after collision)
(M+m)u + 0 = 0 + mv but m ≪ M
Mu + 0 = 0 + mv assuming all the momentum is transferred to the small ball from superball
from (1) v = mu/M ------------------(2)
3. Now apply the principle of conservation of Mechanical energy to the small ball,
(K.E. of small ball just after bounce)+(P.E. of small ball just after bounce) =
(K.E. of small ball at maximum height)+(P.E. of small ball at maximum height)
m
+0 = 0 + mgH
H = new height attained,
From (2)
H = (M²/m²)h