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Devlin:
Steps to the Analytic Method:
1) Use dimensionless form of DE
<math>let \xi = \sqr [(mx\omega}/\hbar)] </math> and <math> K=(2E)/(\hbar\omega). </math>
Then we can use the dimensionless form of the Schrodinger <math> \frac{\partial^2}{\partial x^2}=(\xi^2-K)\psi(x) </math>
We can think of <math> \xi </math> as approximately <math> x </math> and also <math> \psi </math> as approximately <math> e^-(\xi)^2/2) </math>.
2.) Behavior at large
<math> \psi\approx h(\xi)e^(-\xi^2/2) </math>
We use this and hope that <math> h(\xi) </math> is simpler than <math> \psi(\xi) </math>
3.) Substitute <math> \psi </math> into <math> \frac{\partial^2}{\partial x^2}=(\xi^2-K)\psi(x). </math>
Differentiate and then Schrodinger's equation becomes
<math> \frac{\partial^2h(\xi)}{\partial \xi^2}=-2h\xi(\xi)+(K-1)(h(\xi)=0 </math> (A)
4.) Use power series to find a solution.
<math> h(\xi)=\sum a_j \xi^j. </math>.
Differentiate each term twice.
5.) Recursive Equation
Plug equation into (A) and we get a recursive equation that can be illustrated like this:
<math> (blah)(\xi)^0+ (blahblah)(\xi)^1 +(moreblah)(\xi)^2+…=0. </math>
Since the equation needs to hold true for all <math> \xi </math>, the 'blahs' must equal zero. We now have this equation
<math> a_j+2 = (2j+1-K)a_j/[(j+1)(j+2)] </math>
Now all we need to know is a_0 and a_1 and we can find all a.
6.) Normalize
This is good, but not all the solutions that are found are normalizable. To get normalizable solutions, we need the power series to terminate. To do this, we need the numerator to go to zero. That is <math> 2j+1-K=0, </math> so <math>K=2j+1.</math>
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