Want this question answered?
Momentum = (mass) times (velocity) = 0.25 x 40 = 10 kg-m/sec
A 250 g ball travels at a velocity of 40 m/s. Its momentum = mv where m is mass in kg and v is velocity in m/s mv = 250/1000 x 40 10 kg m/s
The green ball has more mass than the orange ball. r=mv Momentum = mass x velocity.
The highest point is the point where the ball's velocity transitions from upward to downward. At that instant, the ball's speed, velocity, momentum, and kinetic energy are all exactly zero.
Momentum is P = mv or Momentum = mass x velocity so the momentum of that ball would be 6 x 4.5 = 27kg m/s
Momentum = (mass) times (velocity) = 0.25 x 40 = 10 kg-m/sec
A 250 g ball travels at a velocity of 40 m/s. Its momentum = mv where m is mass in kg and v is velocity in m/s mv = 250/1000 x 40 10 kg m/s
Momentum is mass x velocity, so it would also depend on each ball's velocity.
The green ball has more mass than the orange ball. r=mv Momentum = mass x velocity.
The highest point is the point where the ball's velocity transitions from upward to downward. At that instant, the ball's speed, velocity, momentum, and kinetic energy are all exactly zero.
Momentum is P = mv or Momentum = mass x velocity so the momentum of that ball would be 6 x 4.5 = 27kg m/s
Tennis balls are lighter than cricket balls. Therefore less mass. If a tennis ball travels at the same speed its momentum (mass x velocity) is lower. Therefore less momentum an easier to stop. Short answer, less mass and same speed means less momentum
Momentum is calculated by taking the product of mass times velocity. Thus, a moving tennis ball would have a nonzero momentum. However, since a tennis ball has a relatively small mass, it would need to have a high velocity in order to have a large value for its momentum. Since velocity is a vector (having both a magnitude and a direction), momentum is also a vector. When a tennis player hits a tennis ball with his racket, he imparts a force onto the tennis ball, which changes the direction of its momentum to return it over the net. (The value for this change in momentum is called impulse, which is equal to the product of the force applied and the time for which it is applied.)
Since momentum equals mass times velocity, the metal ball's momentum is 2N/s (Newton seconds).
the momentum would be 27.44 kg*m/s
Yes. The ball is moving, right? It has both momentum (mass times velocity) and kinetic energy (one-half the mass times the velocity squared). When you hit the ball with the bat, the energy of the ball is transferred to the bat, and the bat imposes its own energy and momentum to the ball.
Yes. Momentum is simply the product of mass x velocity. If the bowling ball happens to be on the shelf, then even a housefly or a falling piece of tissue has more momentum.