Phy5646/CG coeff example1: Difference between revisions

Revision as of 04:24, 10 April 2010

Find the CG coefficients

$1\rangle :{\dfrac {1}{2}}\otimes 1={\dfrac {3}{2}}\oplus {\dfrac {1}{2}}$

Answer

The addition of $j_{1}=s={\frac {1}{2}}$ and $j_{2}=l=1$ is encountered, for example, in the p-state of an electron. This state is characterised by orbital quantum number $j_{1}=s={\frac {1}{2}}$ and spin quantum number $j_{2}=l=1$ . Obviously the possible values of magnetic quantum number for $j_{1}=s={\frac {1}{2}}$ are $m_{s}={\frac {1}{2}},-{\frac {1}{2}}$ and those for $j_{2}=l=1$ are $m_{l}=1,0,-1$ . The allowed values of the total angular momentum are between $|j_{1}-j_{2}|\leq j\leq j_{1}+j_{2}$ hence $j={\frac {3}{2}},{\frac {1}{2}}$ . To calculate the relevant Clebsch–Gordan coefficients, we have to express the basis vectors $|jmj_{1}j_{2}\rangle$ in terms of $|{\dfrac {1}{2}},1,m_{1}m_{2}\rangle$

Eigenvectors $|jm\rangle$ associated with $j={\dfrac {3}{2}}$ :

The state $|{\dfrac {3}{2}},{\dfrac {3}{2}}\rangle$ is given by,

 $|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {3}{2}}\rangle$  =  $|{\dfrac {1}{2}},1,{\dfrac {1}{2}},1\rangle$

Corresponding CG coefficient, $\langle {\dfrac {1}{2}},1,{\dfrac {1}{2}},{\dfrac {1}{2}}$ $|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {3}{2}}\rangle$ = 1

Now $|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {1}{2}}\rangle$ can be found by

Applying $J_{-}$ to $|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {3}{2}}\rangle$ and

$(J_{1-}+J_{2-})$ to $|{\dfrac {1}{2}},1,{\dfrac {1}{2}},1\rangle$ and the equating the two results,

$J_{-}|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {3}{2}}\rangle$ = $(J_{1-}+J_{2-})|{\dfrac {1}{2}},1,{\dfrac {1}{2}},1\rangle$

$J_{-}|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {3}{2}}\rangle$ = $\hbar {\sqrt {{\frac {3}{2}}\left({\frac {3}{2}}+1\right)-{\frac {3}{2}}\left({\frac {3}{2}}-1\right)}}|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {1}{2}}\rangle$

or $J_{-}|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {3}{2}}\rangle$ = $\hbar {\sqrt {3}}|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {1}{2}}\rangle$

Now $(J_{1-}+J_{2-})|{\dfrac {1}{2}},1,{\dfrac {1}{2}},1\rangle$ = $\hbar {\sqrt {{\frac {1}{2}}\left({\frac {1}{2}}+1\right)-{\frac {1}{2}}\left({\frac {1}{2}}-1\right)}}|{\dfrac {1}{2}},1,-{\dfrac {1}{2}},1\rangle$ + $\hbar {\sqrt {1\left(1+1\right)-1\left(1-1\right)}}|{\dfrac {1}{2}},1,{\dfrac {1}{2}},0\rangle$

$(J_{1-}+J_{2-})|{\dfrac {1}{2}},1,{\dfrac {1}{2}},1\rangle$ = $\hbar |{\dfrac {1}{2}},1,-{\dfrac {1}{2}},1\rangle$ + $\hbar {\sqrt {2}}|{\dfrac {1}{2}},1,{\dfrac {1}{2}},0\rangle$

$J_{-}|{\dfrac {1}{2}},1,{\dfrac {3}{2}},{\dfrac {1}{2}}\rangle$

Revision as of 03:54, 10 April 2010 (view source) ShantanuChakraborty (talk \| contribs) (→‎Find the CG coefficients) ← Older edit		Revision as of 04:24, 10 April 2010 (view source) ShantanuChakraborty (talk \| contribs) (→‎Find the CG coefficients) Newer edit →
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	<math> (J_{1-} +J_{2-})\|\dfrac{1}{2}, 1, \dfrac{1}{2},1\rangle</math> = <math>\hbar \|\dfrac{1}{2}, 1, -\dfrac{1}{2},1\rangle</math> + <math>\hbar \sqrt{2} \|\dfrac{1}{2}, 1, \dfrac{1}{2},0\rangle</math>		<math> (J_{1-} +J_{2-})\|\dfrac{1}{2}, 1, \dfrac{1}{2},1\rangle</math> = <math>\hbar \|\dfrac{1}{2}, 1, -\dfrac{1}{2},1\rangle</math> + <math>\hbar \sqrt{2} \|\dfrac{1}{2}, 1, \dfrac{1}{2},0\rangle</math>

			<math> J_{-} \|\dfrac{1}{2}, 1, \dfrac{3}{2},\dfrac{1}{2}\rangle</math>

Phy5646/CG coeff example1: Difference between revisions

Revision as of 04:24, 10 April 2010

Find the CG coefficients

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