6.1 - Further Momentum

Question 1

What is an elastic collision

Answer 1

A collision in which kinetic energy is conserved is called an elastic collision

In general, these are rare. A Newton’s cradle is an example that is nearly perfectly elastic (a tiny amount of energy is lost as sound)

A collision caused by non-contact forces, such as alpha particles being scattered by a nucleus is perfectly elastic

Question 2

What can elastic collision occur

Answer 2

When forces are non contact

Question 3

What is an inelastic collision

Answer 3

The total momentum after a collision must be identical to the total momentum prior to it. However, if we calculate the total kinetic energy before and after, we invariably find that the total is reduced by the collision.

Some of the kinetic energy is transferred into other forms such as heat and sound. A collision in which total kinetic energy is not conserved is called an inelastic collision.

Question 4

What’s important to remember when considering a scenario as inelastic or elastic

Answer 4

Remember that the idea of energy conservation, when considered in order to decide whether a collision is elastic or inelastic, only relates to the kinetic energy. Total energy in all forms must always be conserved !

Question 5

How can we investigate elastic and inelastic collisions

Answer 5

You can investigate elastic and inelastic collisions in the school laboratory. If you cause head on collisions, and record the mass and velocity of each trolley before and after the collisions, you then calculate the momentum at each stage. This should be conserved.
You can also calculate the kinetic energy before and after the collisions.

Real cars are designed to absorb as much kinetic energy as possible when they crash. This reduces the energy available to cause injury to the passengers. - crumple zones

Question 6

How can we combine the kinetic energy and momentum equations - what is this useful for?.

Answer 6

E(subscript k) = 1/2mv^2 and v = p/m

Therefore, E(subscript k) = p^2/2m

This formula is particularly useful for dealing with the kinetic energy of subatomic particles travelling at non-relativistic speeds - that is, much slower than the speed of light

Question 7

How can particle collisions be used

Answer 7

We can use particle collisions in experiments to determine the nature of fundamental particles.

The large hadron collider experiment at CERN uses the conservation of momentum to identify the particles based on calculating the mass. This can be done by colliding particles produced in the experiment with known particles in the detector

If we know the mass and speed of one particle and the speed of the unknown, we can calculate the mass which might correspond to a known particle - so we can identify it.

Question 8

Define an elastic collision

Answer 8

An elastic collision is a collision in which total kinetic energy is conserved

Question 9

Define an inelastic collision

Answer 9

An inelastic collision is a collision in which total Kingston energy is not conserved

Question 10

How do we calculate momentum in 2 dimensions

Answer 10

Momentum should be conserved in each dimension separately. So we resolve vector movements entering a collision into components in each dimension (usually call them the x and y direction) and then calculate following the conservation of momentum in each dimension.

After this, we can recombine component vectors to give us an overall vector after the collision.

Question 11

How can we investigate impulse, core practical

Answer 11

In an earlier practical, we saw how you can investigate the change in momentum over time for a trolley that is subject to a constant accelerating force. Using the same apparatus, you could again record how different forces acting over different time periods cause the trolley to accelerate to different velocities. From these results, you can calculate the impulse applied in each case, as I = F x triangle t , triangle p = triangle mv

A graph of impulse on the y axis against change in velocity on x axis should give a straight best fit line through the origin. This straight line verifies the impulse equation, and the gradient of it will give the mass of the accelerating trolley and weights.

The book says make sure you have a good understanding of this practical as your understanding of the experimental method may be assessed in your examinations - ay hint hint 😰🤩

Question 12

What is impulse

Answer 12

The product of a force applied for a certain time (F x triangle t) is known as impulse, this is equal to the change in momentum

Impulse (Ns) = force (N) x time (s) = change in momentum (kgm/s)

Impulse = F x triangle t = triangle p

To stop something moving, we need to remove all of its momentum. This idea allows us to calculate the impulse needed to stop an object moving. If we know how long a force is applied, we could work out the size of that force.

Question 13

Tell me about deep space collisions

Answer 13

There is an asteroid named Apophis which has a small change of colliding with earth in 2035, 2036 or maybe 2037, and there have been some calls for a mission to crash a spacecraft into Apophis in order to deviate out of harms way. In order to change its momentum and direction.

Question 14

Tell me about investigating 2D collisions

Answer 14

You can investigate two dimensional collisions in the school laboratory. We can analyse video footage of an objects movement, frame by frame, we can calculate any changes in velocity. With measurement scales in two dimensions,the components of velocity in each dimension can be isolated. Thus, separate calculations can be made in each dimension, in order to verify the conservation of momentum in 2D.

Question 15

Define impulse

Answer 15

The impulse is force acting for a certain time causing a change in an objects momentum.

Impulse = F x triangle t