31.2: Perfectly Inelastic Collisions

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The easiest type of one-dimensional collision to analyze is a perfectly inelastic collision. In this type of collision, all of the initial kinetic energy is converted into heat and into work that deforms the bodies. After the collision, the two bodies stick together, forming a single combined mass equal to the sum of the original masses. Momentum is conserved, but not kinetic energy.

To analyze this situation, consider two bodies moving along the \(x\) axis: one of mass \(m_{1}\) moving with initial velocity \(v_{1 i}\), and one of mass \(m_{2}\) moving with initial velocity \(v_{2 i}\). After the collision, the two bodies stick together, forming a single body of mass \(m_{1}+m_{2}\) moving with velocity \(v\). The question is: given the masses \(m_{1}\) and \(m_{2}\) and initial velocities \(v_{1 i}\) and \(v_{2 i}\), what is the final velocity \(v\) of the combined mass?

To answer this question, we make use of the principle of conservation of momentum. Before the collision, the initial momentum \(p_{i}\) of the system is the sum of the momenta of all the bodies in the system:

\[p_{i}=m_{1} v_{1 i}+m_{2} v_{2 i} .\]

After the collision, the total energy of the system is

\[p_{f}=\left(m_{1}+m_{2}\right) v\]

Since momentum is conserved, the initial and final momenta must be the same: \(p_{i}=p_{f}\), so

\[m_{1} v_{1 i}+m_{2} v_{2 i}=\left(m_{1}+m_{2}\right) v\]

The final velocity \(v\) is then

\[v=\frac{m_{1} v_{1 i}+m_{2} v_{2 i}}{m_{1}+m_{2}}\]

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