Explanation Introduction: The total mechanical energy of an object is divided between its potential energy and kinetic energy. The potential energy is the energy within an object, due to the position of the object. Kinetic energy is the energy possessed by an object because of its motion. In other words, it is the work done on a body to increase its velocity from rest. It can be calculated by the formula KE = 1 2 m v 2 . The child applies the force to the front wagon. It allows the front wagon to gain some velocity to move forward. This velocity, caused by force, will increase the kinetic energy of the front wagon. The rear wagon is tied to the front wagon with a spring. As the first wagon moves forward, the spring gets elongated and stores potential energy in it. When the spring gains its maximum potential energy, it will apply force to the rear wagon, and the rear wagon will also move. This velocity, gained by the rear wagon, will increase the kinetic energy of the rear wagon. Conclusion: Thus, the change in the amount of potential and kinetic energy over time is shown below

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Chapter 7, Problem 36TP

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The change in the relative amount of potential and kinetic energy of the given system with time.

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Chapter 7, Problem 35TP

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