QUESTION 2

Objectives:

I . identify potential and kinetic energy in a situation and draw corresponding energy bar charts,

II . calculate gravitational and elastic potential energy,

III . draw & analyze potential energy functions, and (d) use conservation of energy to relate the total energy at one time to total energy at another time.

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Bungee Jump: you will step off with zero initial vertical velocity from a platform a height h above the ground. The bungee cord will act like a giant extensional spring that will, you hope, provide an upward force on becoming taut. After weighing you (you have a mass M), the operator has selected a bungee cordwith an un-stretched length of d and a spring constant of k.

Consider yourself to be a single point – i.e., use the particle model.

Choosing the ground as your origin (and the z-axis directed upwards), answer the following questions about your bungee jumping adventure in terms of M, h, d, k, z, and the gravitational field strength, g. Answer with variables.

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a)

Write an expression for the stretching ?L of the cord in terms of d and z and for the total potential energy U of the jumper-bungee-Earth system for each situation (consider the latter two situations together).

b)

Which type of potential energy ( UG or US ) is largest for large z (early in the fall)? For small z (late in the fall)?

c)

Sketch a graph of your gravitational potential energy, UG(z) vs your height, z, from z = 0 to z = h, on the left plot. Then sketch a graph of your elastic potential energy, US(z) on the center plot. Finally on the rightmost plot, sketch a graph of your total potential energy1 U(z) = UG(z) + US(z). Do these plots on your own without the help of a computer or calculator.