Assuming it is a perfect sphere (or close to it), you can use the formula for a sphere. V = (4/3) pi r3.
Yes, the surface can affect the bounce of a ball. A harder surface like concrete will result in a higher bounce compared to a softer surface like grass or sand. The elasticity and friction of the surface play a role in how the ball rebounds.
When a ball is rolled on a rough surface, the friction between the ball and the surface causes the ball to slow down more quickly compared to when rolled on a smooth surface. This friction converts some of the kinetic energy of the ball into heat, resulting in the ball losing speed and coming to a stop sooner.
It does because when the ball hits the surface and the surface magnified would look rugged anyways when the ball hits the surface the friction pulls on the ball causind it to slow down and if you roll a brick down a hill you will find it will stop easier than a ball smooth surface
When you roll a ball on a rough surface, the friction between the ball and the surface will slow it down more than if it was on a smooth surface. The rough surface causes the ball to lose some of its kinetic energy as heat due to friction, resulting in a shorter overall distance traveled compared to rolling on a smooth surface.
The ball with the least amount of friction will roll the farthest. This typically means a ball with a smooth and spherical surface. The surface on which the ball is rolling will also affect its distance.
Yes, the surface can affect the bounce of a ball. A harder surface like concrete will result in a higher bounce compared to a softer surface like grass or sand. The elasticity and friction of the surface play a role in how the ball rebounds.
it will leave the surface of the other ball roughly 1/4 of the way down to the other end.
When a ball is rolled on a rough surface, the friction between the ball and the surface causes the ball to slow down more quickly compared to when rolled on a smooth surface. This friction converts some of the kinetic energy of the ball into heat, resulting in the ball losing speed and coming to a stop sooner.
It does because when the ball hits the surface and the surface magnified would look rugged anyways when the ball hits the surface the friction pulls on the ball causind it to slow down and if you roll a brick down a hill you will find it will stop easier than a ball smooth surface
Surface area of a ball or a sphere = 4*pi*radius squared
A ball rolling along any surface will be slowed by friction. Different materials used for the ball and the rolling surface will affect the distance a ball will roll but in general, the smoother and more polished the surface is, the further a ball will roll.
When you roll a ball on a rough surface, the friction between the ball and the surface will slow it down more than if it was on a smooth surface. The rough surface causes the ball to lose some of its kinetic energy as heat due to friction, resulting in a shorter overall distance traveled compared to rolling on a smooth surface.
The ball with the least amount of friction will roll the farthest. This typically means a ball with a smooth and spherical surface. The surface on which the ball is rolling will also affect its distance.
Factors that affect the bounce of a dropped ball include the material and elasticity of the ball, the surface it lands on, the height from which it is dropped, and the force with which it is dropped. The higher the drop height and the greater the force of impact, the higher the ball will bounce, provided the surface allows for a rebound.
A smooth and flat surface with minimal friction, such as a polished marble floor, will allow a ball to roll the fastest. The lack of friction will reduce resistance and enable the ball to maintain its speed for longer distances.
a ball would roll better on one surface vs the other because one surface may have more friction the the other surface. For example a smooth surface like a polished wooden floor would have a ball roll better than a carpet where the hairs are stopping the progression of the ball.
gravity, buoyancy, surface tension.