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Schr ö dinger’s Equation

Schr ö dinger’s Equation. Class Objectives. How do we get at the information in the wave function? Introduce Schrödinger's equation. Develop the time independent Schrödinger's Equation (TISE). Schr ö dinger’s Equation. The fundamental problem in QM is:. Schr ö dinger’s Equation.

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Schr ö dinger’s Equation

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  1. Schrödinger’s Equation

  2. Class Objectives • How do we get at the information in the wave function? • Introduce Schrödinger's equation. • Develop the time independent Schrödinger's Equation (TISE).

  3. Schrödinger’s Equation • The fundamental problem in QM is:

  4. Schrödinger’s Equation • The fundamental problem in QM is: given the wave function at some instant t=0, find the wave function at a subsequent time.

  5. Schrödinger’s Equation • The fundamental problem in QM is: given the wave function at some instant t=0, find the wave function at a subsequent time. • The wave function gives the initial information.

  6. Schrödinger’s Equation • The fundamental problem in QM is: given the wave function at some instant t=0, find the wave function at a subsequent time. • The wave function gives the initial information. • is determined from the Schrödinger equation.

  7. Schrödinger’s Equation • In developing his theory, Schrödinger adopted de Broglie’s equations: , • As well he defined the total energy E as

  8. Schrödinger’s Equation • For a particle acted on by a force F, must be found from Schrödinger's wave equation.

  9. Schrödinger’s Equation • Schrödinger's wave equation for 1D is written as:

  10. Schrödinger’s Equation • Schrödinger's wave equation for 1D is written as: • U(x) is the potential energy function for the force F. ie.

  11. Schrödinger’s Equation • How do we obtain an equation for ?

  12. Schrödinger’s Equation • How do we obtain an equation for ? • Schrödinger's equation is a partial differential equation for in terms of two variables.

  13. Schrödinger’s Equation • How do we obtain an equation for ? • Schrödinger's equation is a partial differential equation for in terms of two variables. A standard technique is to look for solutions having separable form.

  14. Schrödinger’s Equation • How do we obtain an equation for ? • Schrödinger's equation is a partial differential equation for in terms of two variables. A standard technique is to look for solutions having separable form. Ie.

  15. Schrödinger’s Equation • How do we obtain an equation for ? • Schrödinger's equation is a partial differential equation for in terms of two variables. A standard technique is to look for solutions having separable form. Ie. • Where is a function of x only and a function of t only.

  16. Schrödinger’s Equation • Substituting into Schrödinger's equation we get:

  17. Schrödinger’s Equation • Substituting into Schrödinger's equation we get: • Dividing by gives

  18. Schrödinger’s Equation • LHS is a function of x only.

  19. Schrödinger’s Equation • LHS is a function of x only. • RHS is a function of t only.

  20. Schrödinger’s Equation • LHS is a function of x only. • RHS is a function of t only. • Since changing t cannot effect LHS

  21. Schrödinger’s Equation • LHS is a function of x only. • RHS is a function of t only. • Since changing t cannot effect LHS (changing x does not affect RHS)

  22. Schrödinger’s Equation • LHS is a function of x only. • RHS is a function of t only. • Since changing t cannot effect LHS (changing x does not affect RHS), the differential can be separated into two ODEs.

  23. Schrödinger’s Equation • Both sides must equal to the same separation constant.

  24. Schrödinger’s Equation • Both sides must equal to the same separation constant. So that,

  25. Schrödinger’s Equation • S1 is a 1st order ODE (Φ as a function of t). These have the solution

  26. Schrödinger’s Equation • S1 is a 1st order ODE (Φ as a function of t). These have the solution

  27. Schrödinger’s Equation • S1 is a 1st order ODE (Φ as a function of t). These have the solution • NB: You should verify this!

  28. Schrödinger’s Equation • S1 is a 1st order ODE (Φ as a function of t). These have the solution • NB: You should verify this! • It is easy to show that C = E, the total energy.

  29. Schrödinger’s Equation • S1 is a 1st order ODE (Φ as a function of t). These have the solution • NB: You should verify this! • It is easy to show that C = E, the total energy. • Thus

  30. Schrödinger’s Equation • S1 is a 1st order ODE (Φ as a function of t). These have the solution • NB: You should verify this! • It is easy to show that C = E, the total energy. • Thus • And

  31. Schrödinger’s Equation • is the time independent Schrödinger equation.

  32. Schrödinger’s Equation • is the time independent Schrödinger equation. • We can write the solution to Schrödinger equation as

  33. Schrödinger’s Equation • is the time independent Schrödinger equation. • We can write the solution to Schrödinger equation as • The expression gives a relationship between the time independent and dependent wave functions.

  34. Schrödinger’s Equation • is the time independent Schrödinger equation. • We can write the solution to Schrödinger equation as • The expression gives a relationship between the time independent and dependent wave functions. • The solutions for are that of planes. ie

  35. Schrödinger’s Equation • The functions of are called eigenfunctions.

  36. Schrödinger’s Equation • The functions of are called eigenfunctions. • Solutions of Schrödinger’s equation are stationary states.

  37. Schrödinger’s Equation • The functions of are called eigenfunctions. • Solutions of Schrödinger’s equation are stationary states. • This because they are time independent and the probability distributions are time independent.

  38. Schrödinger’s Equation • The functions of are called eigenfunctions. • Solutions of Schrödinger’s equation are stationary states. • This because they are time independent and the probability distributions are time independent.

  39. Schrödinger’s Equation • Because the probabilities are static they can be calculated from the time independent wave form.

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