Use conservation of momentum in each direction:  and 

The initial momentum in the x direction is provided only by the first object.

This also equals the final x-momentum, when the two objects move together at the same velocity.

The initial momentum in the y direction is provided only by the second object.

Again, this equals the final y-momentum.

Combine the two velocities using the Pythagorean theorem.

The momentum is equal to Sam's total mass times his velocity. His velocity can be found from his potential energy, using conservation of energy. Keep in mind, his total mass includes the mass of his sled.

PE = mgh = (50kg + 10kg) * 10m/s² * 50m

PE = 30,000J

KE = 30,000J = 1/2mv² = 1/2(60kg)(v²)

v² = 1000 m²/s² = 31.2m/s

p = mv = 60 kg * 31.2 m/s = 1898 kg*m/s

If you had used 30J in place of 30kJ in the KE calculation, you would have chosen 60kg*m/s

Kinetic energy emphasizes velocity, by squaring the velocity term.

KE = 1/2mv²

Sally's KE = 1/2(52 kg)(12 m/s)² = 3,744J

John's KE = 1/2(80 kg)(8m/s)² = 2,560J

p = mv

Sally's Momentum = 52kg * 12m/s = 624 kg*m/s

John's Momentum = 80kg * 8m/s = 640 kg*m/s

Apply conservation of momentum before and after the collision.

.

Taking left to be the negative direction, and noting that Bob's initial momentum is 0 since he is at rest, we can use the provided information to see that  .

Solving for , we get . Since this answer is positive, Bob's momentum is in the positive direction (to the right).

The difference between an elastic and inelastic collision is that in an elastic collision BOTH momentum and kinetic energy are conserved. Momentum is conserved in any collision, but when a collision is inelastic, kinetic energy is dissipated when the two individual objects combine. This energy can be in the form of heat, explosion, sound, etc. In a totally inelastic collision, the two objects colliding stick together and travel with the same velocity in one direction.

Overall energy is conserved, as the energy is merely transferred from a kinetic form to a non-kinetic form.

We can find the momentum for each object using the momentum formula, .

The momentum formula is . We know that momentum is conserved during the collision, and that the final momentum must be eastward; thus, the initial net momentum must also be eastward, since momentum is a vector. Only one answer choice gives an eastward (positive) momentum.

Answer possibilities:

We can set this up as a conservation of momentum problem. The sum of the initial momentum for each object must equal the sum of the final momentum of each object.

We have two objects and four different velocities. The system must conserve momentum between the time before the collision and after the collision. We are given the mass of each object and their initial velocities.

We are given the magnitude of the billiard ball's final velocity, and told that it changes directions, thus becoming negative. Remember that both velocity and momentum are vector quantities.

Finally, we can solve of the final velocity of the bowling ball. We can predict that the bowling ball's velocity will be positive since the net initial velocity is positive, and the final billiard ball velocity is negative. The bowling ball must compensate for the negative momentum of the billiard ball.

The best way to solve this problem is to use the impulse, or change in momentum. Impulse can be calculate from either of two equations:

We can set these equations equal, and use the given values for mass and velocity to calculate the impulse.

We are given the applied force, allowing us to solve for the time.

Momentum is conserved in both elastic and inelastic collisions. During an elastic collision, kinetic energy is also conserved and the two objects remain separate after impact. During an inelastic collision, kinetic energy is lost to the surroundings and the objects traditionally stick together upon impact. The energy lost in an inelastic collision is generally transformed into heat or sound.

The only time momentum will not be conserved is when an outside force is introduced or the masses of objects do not remain constant.