A-level Physics/Forces, Fields and Energy/Further dynamics

If you have seen collisions involving two objects, you may have noticed that the velocity of one object seems to be passed to the other object. You may also have noticed that heavier objects seem to pass more velocity on to smaller objects, whereas smaller objects seem to pass less velocity to more massive ones.

What is in fact happening is that momentum is being conserved. Momentum is the product of an objects mass and velocity, or ${\displaystyle p=mv}$ . This means that, after a collision, an object that is heavier will have a lower velocity than a lighter object in its place, and vice versa. Momentum is conserved for all collisions. The principle of the conservation of momentum states that:

Momentum is a vector quantity and has the units ${\displaystyle kg\,m\,s^{-1}}$  or ${\displaystyle Ns}$  (Newton-seconds) in the SI system.

Since momentum is conserved, the momentum before a collision is equal to the momentum after a collision. You can use this fact to solve problems involving collisions.

${\displaystyle {\begin{alignedat}{2}Before&=After\\m_{1}u_{1}+m_{2}u_{2}&=m_{1}v_{1}+m_{2}v_{2}\\\end{alignedat}}}$ 

For instance, a ball is moving at 3 m/s with mass 3 kg. It hits another ball with mass 1 kg moving at 2 m/s; the two balls collide and the second ball rebounds at 4 m/s. Find the velocity at which ball 1 is moving:

${\displaystyle {\begin{alignedat}{2}Before&=After\\m_{1}u_{1}+m_{2}u_{2}&=m_{1}v_{1}+m_{2}v_{2}\\3\times 3+2\times 1&=3v+1\times 4\\11&=3v+4\\11-4&=3v\\7&=3v\\v&={\frac {7}{3}}\\\end{alignedat}}}$ 

So the velocity at which ball 1 is moving after the collision is 2.3 m/s (7/3)m/s 1

Newton's first law of motion edit

Newton's second law of motion edit

Originally, you learnt this to be:

However, since you now know that a force changes the rate of change of momentum of an object, we can use a more accurate interpretation of Newton's second law:

Newton's third law of motion edit