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Today we focus on the following two points.
In the last class the power series method is used:
<math>U(\xi)=\sum_{n=0}^\infty a_n \xi^2</math>
Substitute it into differential equation derives the recursive relation:
<math>a_k=\frac{(\nu+1)(\nu+2)…(\nu+k)(-\nu)(-\nu+1)…(-\nu+k-1)}{(k!)^2} a_0</math>
<math>a_0</math> is determined by normalization.
Now consider the convergence requirement. Just as the simple harmonic oscillator, for normalizable solutions the power series must terminate. And if <math>\nu</math> is an integer, <math>a_k</math> will be zero if k is large enough. If <math>\nu</math> is negative, there exists a corresponding positive <math>\nu</math> that leads to the same recursive relation. So <math>\nu</math> can be limited to non-negative numbers:
<math>\nu=0,1,2,…</math>
<math>\alpha=\nu(\nu+1)=0,2,6,12,…</math>
Generally <math>P_\nu (z) </math> is called Legendre function, <math>\nu</math> is any real number. If convergence is important, <math>\nu=l</math> is integer, we deal with the Legendre polynomial <math>P_l (z) </math>
The equation is written as:
<math>\frac{d}{dr} (r^2 \frac{dR}{dr})- \frac{2mr^2}{\hbar^2}[V®-E]R=l(l+1)R</math>
<math>l(l+1)</math> is related with the square of angular momentum:
<math>L^2=l(l+1)\hbar^2</math>
Define <math> R®=\frac{u®}{r}</math>, then the differential equation is transformed from <math>R®</math> to <math>u®</math>:
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