Chapter 6--Potential Energy of a Spring System Surroundings.

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Presentation transcript:

Chapter 6--Potential Energy of a Spring System Surroundings

Potential Energy of an Ideal Spring

Potential Energy Diagram for an ideal spring

Vertical mass-on-spring Treat the equilibrium length of the spring as if it is the unstretched length of the spring. Then, you can neglect the gravitational force on the object. The spring becomes a compressible spring.

Example A spring has a stiffness 100 N/m. You stretch it 20 cm from its unstretched position. How much work did you do on the spring? If you stretch it an additional 20 cm, how much additional work did you do on the spring?

Example You hang 0.25 kg on a spring of stiffness 10 N/m. You pull it down 0.05 m from its equilibrium position and release it from rest. How fast is it moving when it reaches the equilibrium position?

Poll A simple harmonic oscillator of a mass m on a spring of stiffness k oscillates with an amplitude A and frequency . If you double the mass m, the energy of the system 1.Increases by factor of 2 2.Decreases by factor of 1/2 3.Increases by factor of 4 4.Decreases by factor of 1/4 5.Increases by factor sqrt(2) 6.Decreases by factor 1/sqrt(2) 7.Stays the same.

Poll A simple harmonic oscillator of a mass m on a spring of stiffness k oscillates with an amplitude A and frequency . If you double the stiffness k, the energy of the system 1.Increases by factor of 2 2.Decreases by factor of 1/2 3.Increases by factor of 4 4.Decreases by factor of 1/4 5.Increases by factor sqrt(2) 6.Decreases by factor 1/sqrt(2) 7.Stays the same.

Poll A simple harmonic oscillator of a mass m on a spring of stiffness k oscillates with an amplitude A and frequency . If you double the amplitude A, the energy of the system 1.Increases by factor of 2 2.Decreases by factor of 1/2 3.Increases by factor of 4 4.Decreases by factor of 1/4 5.Increases by factor sqrt(2) 6.Decreases by factor 1/sqrt(2) 7.Stays the same.

Modeling a chemical bond Morse Potential

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