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The change in momentum of the ball during the collision with the bat is equal to the final momentum of the ball minus the initial momentum of the ball. This change in momentum is a result of the force applied by the bat on the ball during the collision.
The change in momentum of the ball thrown against the wall will be equal to the final momentum minus the initial momentum of the ball.
Due to the greater mass, the momentum will high, hence making its motion difficult to change.
If both balls are moving at the same speed (velocity), the heavier (more massive) will have the greater momentum. Momentum is the product of mass and velocity. With identical velocities, the more massive object will have the greater momentum. If a 34 kg ball and a 35 kg ball are both moving at 8 m/s as asked, then the 34 kg ball will have less momentum than the 35 kg ball.
The green ball would have greater mass than the orange ball. Momentum depends on both mass and velocity, so if they have the same velocity but different momentum, it means their masses must be different.
It is equivalent to the change in momentum of the ball.
The bowling ball has more momentum because momentum is directly proportional to an object's mass and velocity. Since the two balls are moving at the same speed, the greater mass of the bowling ball results in it having more momentum.
The bowling ball is harder to stop because it has a greater mass, and therefore a greater momentum. But the answer is that the bowling ball has a greater mass.
Possibly but not likely.
A moving ball has more momentum than a still bat because momentum is the product of an object's mass and velocity. The ball's mass is likely much smaller than the bat's, but its velocity while in motion gives it a greater momentum than the bat.
Friction between the ball and cloth.
Friction between the ball and cloth.