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Particle in a Box

Particle in a Box. Class Objectives. Introduce the idea of a free particle. Solve the TISE for the free particle case. Particle in a Box. The best way to understand Schr ö dinger’s equation is to solve it for various potentials. Particle in a Box.

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Particle in a Box

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  1. Particle in a Box

  2. Class Objectives • Introduce the idea of a free particle. • Solve the TISE for the free particle case.

  3. Particle in a Box • The best way to understand Schrödinger’s equation is to solve it for various potentials.

  4. Particle in a Box • The best way to understand Schrödinger’s equation is to solve it for various potentials. • The simplest of these involving forces is particle confinement (a particle in a box).

  5. Particle in a Box • Consider a particle confined along the x axis between the points x = 0 and x = L.

  6. Particle in a Box • Consider a particle confined along the x axis between the points x = 0 and x = L. • Inside the box it free but at the edges it experiences strong forces which keep it confined.

  7. Particle in a Box • Consider a particle confined along the x axis between the points x = 0 and x = L. • Inside the box it free but at the edges it experiences strong forces which keep it confined. Eg. A ball bouncing between 2 impenetrable walls.

  8. Particle in a Box • Consider a particle confined along the x axis between the points x = 0 and x = L. • Inside the box it free but at the edges it experiences strong forces which keep it confined. Eg. A ball bouncing between 2 impenetrable walls. U E 0 L

  9. U E: total energy of the particle U: potential containing the particle. The Pd of the walls. E<U E 0 L Particle in a Box

  10. U E: total energy of the particle U: potential containing the particle. The Pd of the walls. E<U E 0 L Particle in a Box • Inside the well the particle is free.

  11. U E: total energy of the particle U: potential containing the particle. The Pd of the walls. E<U E 0 L Particle in a Box • Inside the well the particle is “free”. • This is because is zero inside the well.

  12. U E: total energy of the particle U: potential containing the particle. The Pd of the walls. E<U E 0 L Particle in a Box • Inside the well the particle is “free”. • This is because is zero inside the well. • Increasing to infinity as the width is reduced to zero, we have the idealization of an infinite potential square well.

  13. Infinite square potential U 0 L x

  14. Particle in a Box • Classically there is no restriction on the energy or momentum of the particle.

  15. Particle in a Box • Classically there is no restriction on the energy or momentum of the particle. • However from QM we have energy quantization.

  16. Particle in a Box We are interested in the time independent waveform of the particle. • The particle can never be found outside the well. Ie. in the region

  17. we take, Particle in a Box • Since we get that,

  18. we take, Particle in a Box • Since we get that, • So that

  19. Particle in a Box • The solutions to this equation are of the form for (a linear combination of cosine and sine waves of wave number k)

  20. Particle in a Box • The solutions to this equation are of the form for (a linear combination of cosine and sine waves of wave number k) • The interior wave must match the exterior wave at the boundaries of the well. Ie. To be continuous!

  21. Particle in a Box • Therefore the wave must be zero at the boundaries, x=0 and x=L.

  22. Particle in a Box • Therefore the wave must be zero at the boundaries, x=0 and x=L. • At x=0,

  23. Particle in a Box • Therefore the wave must be zero at the boundaries, x=0 and x=L. • At x=0,

  24. Particle in a Box • Therefore the wave must be zero at the boundaries, x=0 and x=L. • At x=0,

  25. Particle in a Box • Therefore the wave must be zero at the boundaries, x=0 and x=L. • At x=0, • At x=L,

  26. Particle in a Box • Therefore the wave must be zero at the boundaries, x=0 and x=L. • At x=0, • At x=L, • Since , then • , • Recall:

  27. Particle in a Box • From this we find that particle energy is quantized. The restricted values are

  28. Particle in a Box • From this we find that particle energy is quantized. The restricted values are • Note E=0 is not allowed!

  29. Particle in a Box • From this we find that particle energy is quantized. The restricted values are • Note E=0 is not allowed! • N=1 is ground state and n=2,3… excited states.

  30. Particle in a Box • Finally, given k and B we write the waveform as

  31. Particle in a Box • Finally, given k and B we write the waveform as • We need to determine A.

  32. Particle in a Box • Finally, given k and B we write the waveform as • We need to determine A. • To do this we need to normalise.

  33. Particle in a Box • Normalising,

  34. Particle in a Box • Normalising,

  35. Particle in a Box • Normalising,

  36. Particle in a Box • Normalising,

  37. Particle in a Box • Normalising,

  38. Particle in a Box • Normalising,

  39. Particle in a Box • For each value of the quantum number n there is a specific waveform describing the state of a particle with energy .

  40. Particle in a Box • For each value of the quantum number n there is a specific waveform describing the state of a particle with energy . • The following are plots of vs x and the probability density vs x.

  41. Particle in a Box

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