We report investigations of collisions between steel balls and free-ended rods using an electro-mechanical apparatus combined with a Michelson interferometer. Our experimental methodology allows for the evaluation of several collision-initiated parameters, such as collision duration, speed of the inter-material wave pulse, change in rod length, and post-collision center-of-mass velocity. The fractional loss of kinetic energy of the ball-rod system is studied theoretically and experimentally as a function of the rod length. Results are compared to predictions obtained from the elastic-body collision theory. Several aspects of elastic waves are illustrated without recourse to complicated mathematics. The experiment provides significant insight into the physical behavior of colliding solids.

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