8.5 Inelastic Collisions in One Dimension

8.5 Inelastic Collisions in One Dimension

Before and after the collision, try to calculate the internal kinetic energy.

The internal energy is the same at 4.00 J.
You can check the total momentum before and after the collision.

Any one-dimensional elastic collision of two objects can be described with the equations written above.

If needed, the equations can be extended to more objects.

You can vary the number of discs, mass and initial conditions.

Take the elasticity and see what happens.

In an elastic collision, internal energy is conserved.

The forces between colliding objects can remove or add internal energy.
The forms of energy within a system may be changed by internal forces.
When colliding objects stick together, this internal work may transform some internal energy into heat.
When exploding bolts separate a satellite from its launch vehicle, it may be possible to convert stored energy into internal energy.

An inelastic collision is when the internal energy changes.

An inelastic collision is shown in Figure 8.8.

Two objects that have the same mass head toward each other at the same speed.
Their total internal energy is initial.
After sticking together, the two objects come to rest.
The internal energy after the collision is zero.
The collision reduces internal energy to the minimum and still conserves energy.

The internal energy is not conserved.

The internal energy of the system is reduced to zero in this example.

The puck goalie system has negligiblefriction between it and the ice.

An ice hockey goalie catches a hockey puck.

In this inelastic collision, the puck's initial energy is almost completely converted to thermal energy and sound.

The puck-goalie system has zero external force.

The puck and goalie system can be found using the final velocity of the momentum.
The puck and goalie have the same initial and final velocities.
Before and after the collision, the kinetic energies can be calculated and compared.

The puck-goalie system has zero external force.

We know that the goalie is at rest.

The final velocities are equal if the goalie catches the puck.

The recoil velocity is the same as the puck's original velocity.

The goalie is at rest and the internal energy of the system is the hockey puck.

The minus sign indicates that the energy was lost.

In this perfectly inelastic collision, nearly all of the initial internal energy is lost.

Most automobile accidents happen when the objects don't stick together and less of the internal energy is removed.

During a collision, stored energy can be converted into internal energy.

An air track is very smooth.

The motion is only one-dimensional.

The sporting and leisure industry uses elastic and inelastic collision in sports.

We can briefly look at tennis.
In a collision, it is momentum and not force that is important.
A heavier tennis racquet has an advantage over a lighter one.
A softball bat cannot hit a hardball very far.

The location of the tennis ball on the racquet is important, as is the part of the stroke during which the impact occurs.

A tennis player tries to hit the ball on the "sweet spot" on the racquet, where the impact is minimized and the ball is able to be given more speed.
Sports science and technologies use physics concepts.

A tennis, badminton, or other racquet can be found.

The elasticity of a collision between a ball and an object is measured by the ratio of the speeds after and before the collision.

There is a perfectly elastic collision.
A ball bouncing off the floor can be shown to be the height from which the ball is dropped.
For the case of a tennis ball bouncing off a concrete or wooden floor, determine for the cases in Part 1 and for the case of a new tennis ball used on a tennis court.