The acceleration of a bowling ball at rest at the end of the bowling lane is 0 m/s^2. Since the ball is not changing its velocity, it is not experiencing any acceleration.
The momentum of an object is calculated by multiplying its mass by its velocity. We would need to know the mass of the bowling ball in order to calculate its momentum using the formula momentum = mass x velocity. The units for momentum are kg*m/s.
Float the ball in water and calculate the displacement.
The force of the bowling ball colliding with the golf ball causes the golf ball to be redirected in an elastic collision. How fast either travels depends on the friction of the surface and the angle of contact with the bowling ball.Comparative Masses and EnergyIn the collision between a golf ball and a bowling ball, the fact that the bowling ball continues to move (although possibly changed in direction) is a function of the comparative masses of the two. The bowling ball is much more massive, so at normal velocities its kinetic energy exceeds the kinetic energy of the golf ball. In order to "stop" the bowling ball, the golf ball would have to make a perfectly aimed collision, and have a much higher velocity. Quantitatively, the velocity of the golf ball would have to be the inverse ratio of the ratio of the masses of the two balls, so that the kinetic energy (mass times velocity) is equal and in the opposite direction.Example : Golf ball at 45 g, ten pound bowling ball at 4500 g -- the golf ball would have to move at 100 times the velocity of the bowling ball to counteract its kinetic energy. If the bowling ball rolls at 2 m/sec, the golf ball would have to travel at more than 200 m/sec (720 kph or 447 mph), about 3 times a ball's normal velocity off the face of a golf club.
The bowling ball would have more momentum because it has more mass than the golf ball. Momentum is calculated as the product of an object's mass and velocity, so a heavier object moving at the same velocity will have more momentum.
calculate the force of the ball and statistics
To determine the velocity of the ball, you would need to measure the distance the ball traveled in each 0.25-second interval using the ruler. Then, divide the distance by the time interval to calculate the average velocity for each interval. The velocity of the ball would be the average velocity over all the intervals measured.
The adult's bowling ball will have more kinetic energy because it has more mass and is likely moving at a higher velocity compared to the student's bowling ball. Kinetic energy is directly proportional to an object's mass and the square of its velocity, so a heavier ball moving faster will have greater kinetic energy.
It is an example of momentum (sometimes called "inertia"). Velocity x mass. The bowling ball is much, much heavier. With both rolling at the same speed, the bowling ball is harder to stop because it has much more mass.
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 momentum of the bowling ball can be calculated using the formula: momentum = mass x velocity. Plugging in the values, momentum = 6.0 kg x 2.2 m/s = 13.2 kg*m/s.
The golf ball would go faster because it has less mass compared to the bowling ball but the same kinetic energy. The kinetic energy of an object is determined by both its mass and its velocity, so the lighter golf ball would be able to achieve a higher velocity with the same amount of kinetic energy as the heavier bowling ball.