When a ball bounces, what action and reaction forces do the ball and the ground exert?(1 point)%0D%0AResponses%0D%0A%0D%0AA ball and the ground exert forces of the same magnitude, but in opposing directions.%0D%0AA ball and the ground exert forces of the same magnitude, but in opposing directions.%0D%0A%0D%0AThe ball's force is stronger than that of the ground, and they go in the same direction.%0D%0AThe ball's force is stronger than that of the ground, and they go in the same direction.%0D%0A%0D%0AThe ball's force is stronger than that of the ground, and they go in opposite directions.%0D%0AThe ball's force is stronger than that of the ground, and they go in opposite directions.%0D%0A%0D%0AThe ball's force is the same as that of the ground and they go in the same direction.
A ball and the ground exert forces of the same magnitude, but in opposing directions.
The ball and the ground exert forces of the same magnitude, but in opposite directions.
When a ball bounces, the ball and the ground exert forces of the same magnitude but in opposing directions. This is known as Newton's Third Law of Motion, which states that every action has an equal and opposite reaction.
To understand this concept, think about what happens when the ball hits the ground. As the ball collides with the ground, it exerts a downward force on the ground. At the same time, the ground exerts an upward force on the ball. These two forces are equal in magnitude but in opposite directions, causing the ball to bounce back up.
If the ball's force were stronger than that of the ground and they went in the same direction, the ball would not bounce back up. Instead, it would continue to sink into the ground. However, this is not what happens in reality. The upward force exerted by the ground is what gives the ball its bouncing motion.