1 / 41

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.

althea
Télécharger la présentation

Particle in a Box

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  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

More Related