5. The graph included represents the potential energy for a particle oscillating when attached to a spri E (J) 0.04 0.03 0.02 (d) The particle has a mass of 2.0 kg. Find the particle's maximum speed. Graph the speed of the particle as a 0.0H function of . 10 20 30 (e) If the total energy of the particle is tripled, what will be its maximum speed and maximum amplitude?

I solved parts a, b, and c. How do you solve part d and part e?

PLEASE ONLY SOLVE PARTS D AND E!!

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5. The graph included represents the potential energy for a particle oscillating when attached to a spring. (a) Find the spring's equilibrium length lo and constant k. (b) The turning points are 10. cm and 30. cm. Find the max- E (J) imum amplitude and maximum kinetic energy of the par- 0.04 ticle. 0.03 (c) Sketch a graph of the particle's kinetic energy as a func- tion of position x. What is the shape of this graph? 0.02 (d) The particle has a mass of 2.0 kg. Find the particle's 0.01 maximum speed. Graph the speed of the particle as a function of x. x (cm) 40 10 20 (e) If the total energy of the particle is tripled, what will be its maximum speed and maximum amplitude? 30

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5. The graph included represents the potential energy for a particle oscillating when attached to a spring. E (J) 0.04 0.03 0.02 (d) The particle has a mass of 2.0 kg. Find the particle's 0.01 maximum speed. Graph the speed of the particle as a function of x. x (cm) 40 10 20 (e) If the total energy of the particle is tripled, what will be its maximum speed and maximum amplitude? 30