Understanding Acceleration and Forces: Exploring the Physics of Ball Bouncing

In summary: During collision, the zero velocity is reached when both wall and ball are distorted form initial shape. Unless thy are both perfectly "plastic", the force won't be zero. Think about compressing a spring by trowing a ball at it. When the ball has zero velocity the spring has maximum compression. So the force exerted by the spring (or wall) on the ball has maximum...
  • #1
Kaneki123
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This example is written in several books, that is if you strike a ball against a wall it applies an action force on the wall and the reaction force from the wall is the reason for the ball bouncing back..Now i have a question here that when you throw the ball, you accelerate it upto some velocity..When the reaction force from wall acts on the ball, there is a deceleration in the ball...As a result, the velocity should become zero or a positive one... Then why does the ball bounce back?
 
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  • #2
Newton's third law does not tell you whether the ball will bounce back from the wall. If you make the ball out of lump of damp clay, it won't bounce back. If you make it out of a lump of rubber, it will. Both still obey Newton's third law: The force of the ball on the wall is, at all times, equal to the force of the wall on the ball.
 
  • #3
Kaneki123 said:
Then why does the ball bounce back?
Because the force keeps acting after the velocity became zero, due to deformation..
 
  • #4
A.T. said:
Because the force keeps acting after the velocity became zero, due to deformation..
So, if we consider an ideal situation in which there is no deformation in the body,and the ball strikes with exactly the same force as the force we use to throw it, the velocity of ball will become zero...right?...
 
  • #5
Kaneki123 said:
So, if we consider an ideal situation in which there is no deformation in the body,and the ball strikes with exactly the same force as the force we use to throw it, the velocity of ball will become zero...right?...
That's the opposite of an ideal situation. It's an indeterminate case. An infinite force exerted over an infinitesimal distance with an infinitesimal duration. Unless you fill in the missing details about elasticity, the result is undefined.
 
  • #6
You have to say that the wall supplies the force that moves the center of gravity of the ball. Without a wall, a compressed ball that is released will just expand back to round without moving. It is the wall on one side, not allowing the expanding ball to expand in that direction, that makes the ball rebound away from the wall.
 
  • #7
Kaneki123 said:
So, if we consider an ideal situation in which there is no deformation in the body,and the ball strikes with exactly the same force as the force we use to throw it, the velocity of ball will become zero...right?...

No. Force = mass * acceleration. So same force produces the same acceleration not the same velocity.

To work out the velocity you need to know how long the force was applied or the distance over which it was applied.
 
  • #8
CWatters said:
No. Force = mass * acceleration. So same force produces the same acceleration not the same velocity.

To work out the velocity you need to know how long the force was applied or the distance over which it was applied.
The wall produces a negative acceleration in the ball...Let's say we throw the ball at the wall...And we are accelerating the ball from rest or zero velocity with some force...The ball moves with constant velocity until it strikes the wall...Let's say that the wall produces the same reaction force as the force we threw the ball with...Now this force will produce a negative acceleration in the ball until its velocity becomes zero...When the velocity becomes zero, no more force will be acting on the ball as the ball would no longer be striking the walll...It would be like deja vu...Please correct me if anything in above example is wrong...
 
  • #9
A ball which is squished against the wall because of the positive velocity with which it initially impacted will still be squished against the wall when it comes to a stop.
 
  • #10
The force during the collision is not constant. So unless the force you use to accelerate the ball has the same profile (F versus t) it does not make sense to say that the reaction force is the same as the force that accelerates the ball. And anyway, there is no relationship between the two processes. The collision force depends on the velocity of the ball. The same velocity of the ball can be reached by a practically infinite variety of forces accelerating the ball in thr initial stage of the process.

And second, during collision, the zero velocity is reached when both wall and ball are distorted form initial shape. Unless thy are both perfectly "plastic", the force won't be zero. Think about compressing a spring by trowing a ball at it. When the ball has zero velocity the spring has maximum compression. So the force exerted by the spring (or wall) on the ball has maximum value.
 
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1. What is acceleration and how does it relate to ball bouncing?

Acceleration is the rate of change of an object's velocity. In the case of ball bouncing, acceleration is the force that causes the ball to change direction and increase in velocity as it bounces off a surface. This acceleration is caused by the force of gravity pulling the ball towards the ground.

2. How does the force of gravity affect the acceleration of a bouncing ball?

The force of gravity is what causes the ball to accelerate towards the ground when it is dropped. As the ball bounces, the force of gravity pulls it back towards the ground, causing it to accelerate again. The acceleration due to gravity is constant and is approximately 9.8 meters per second squared.

3. What other factors can affect the acceleration and bouncing of a ball?

Other factors that can affect the acceleration and bouncing of a ball include the surface it bounces on, the shape and material of the ball, and any external forces acting on the ball (such as air resistance or friction). These factors can alter the amount of force and energy transferred during the bounce, resulting in variations in the ball's acceleration and bounce height.

4. How does the angle of impact affect the acceleration and bouncing of a ball?

The angle of impact, or the angle at which the ball hits the surface, can greatly affect the acceleration and bouncing of a ball. When the ball hits the surface at a shallow angle, it will have a longer contact time with the surface and thus a lower acceleration and bounce height. On the other hand, when the ball hits the surface at a steep angle, it will have a shorter contact time and a higher acceleration and bounce height.

5. What is the relationship between the elasticity of a ball and its acceleration and bouncing?

The elasticity of a ball, or its ability to regain its shape after being compressed, is directly related to its acceleration and bouncing. A more elastic ball will experience a greater acceleration and bounce height because it can store and release more energy during the bounce. A less elastic ball will have a lower acceleration and bounce height because it loses more energy as it compresses and deforms upon impact with the surface.

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