Have you ever asked yourself how much energy or effort it really takes to dribble a basketball? Energy can only mean one thing: the strength required in a physical or mental activity such as basketball. Every time someone would bounce a basketball on the floor it has to transmit energy for the ball to come back into the air, or into your hands. Without the force of energy, you couldn’t handle the ball like the way you’re supposed to in the game. Why is it when you stop dribbling a basketball, the ball stops bouncing? Being a basketball player requires you to put force onto the ball, to make the ball bounce. Every time you dribble the ball energy is required. In this experiment you will see how the ball bounces on different surfaces such
…show more content…
As the ball drops, energy is stored inside. Potential energy plays a role in the height of basketball. Once the ball is positioned, the ball tends to have more potential energy. Having the force of gravity on the ball and us, velocity the rate of change of the position of an object increases because of gravity. The moment the basketball hits the floor, and impacts the surface, it tends to bounce higher.
An idea for this experiment is to understand the velocity, momentum, physics, and potential energy. Dribbling a basketball, just understands what surfaces tend to bounce higher according to Newton’s second law of motion. Newton has a formula for the motion which is represented as F = MA. When the ball is dropped, the ball moves. The reason for the ball moving is because the potential energy is being transmitted into kinetic energy or the energy of motion. Newton used other things than acceleration in the second law. Newton called this quantity momentum, but he represents it with quantity of motion. Bouncing a basketball doesn’t take much effort except, the energy that it exerts.
According to scientists who have studied the energy or effort it takes to bounce a basketball, researchers say the ball can never reach its original height that you first dropped it too. This is proven because as the ball is falling it loses its energy to air friction. It loses it to air friction