Phy5646/character: Difference between revisions

Latest revision as of 20:40, 25 April 2010

Angular Momentum Addition by Characters

Rotation matrices $e^{{\mathit {i}}{{\vec {\omega }}.{\vec {J}}}}$ are $(2{\mathit {j}}+1)\times (2{\mathit {j}}+1)$ matrix functions of rotating angles ${\vec {\omega }}$ in some representation of spin ${\mathit {j}}$ . To indicate more explicitly the representation we are in we write them as $D_{\mathit {j}}({\vec {\omega }})$ .Let us define the character by $\chi _{\mathit {j}}({\vec {\omega }})={\mathit {tr}}\;D_{\mathit {j}}({\vec {\omega }})$ For a rotation about the z-axis, the rotation matrix is diagonal

$D_{\mathit {j}}(\phi {\hat {z}})=\;diag(e^{{\mathit {ij}}\phi }e^{{\mathit {i(j-1)}}\phi }...e^{-{\mathit {ij}}\phi })$

and the character is easy to compute

$\chi _{\mathit {j}}(\phi )=\sum _{\mathit {m=-j}}^{\mathit {j}}\;e^{\mathit {im\phi }}$

$={\frac {\epsilon ^{\mathit {j+1}}-\epsilon ^{-{\mathit {j}}}}{\epsilon -1}}\;\;\;where\;\;\epsilon =e^{\mathit {i\phi }}$

$={\frac {sin({\mathit {j+{\frac {1}{2}})\phi }}}{sin({\frac {\phi }{2}})}}$

But any rotation may be brought to diagonal form by a similarity transform, so this is the most general character. It depends on the rotation angle, not the direction.

If we tensor together the states $|{\mathit {j_{1}m_{1}}}\rangle$ and $|{\mathit {j_{2}m_{2}}}\rangle$ , they transform under the tensor product representation $D_{\mathit {j_{1}}}\times D_{\mathit {j_{2}}}$ .These matrices have characters which are just products of the elementary characters.

$D_{\mathit {j_{1}}}\times D_{\mathit {j_{2}}}:\;\;\;\chi _{}{\mathit {j_{1}\times {\mathit {j_{2}}}}}(\phi )=\chi _{\mathit {j_{1}}}(\phi )\chi _{\mathit {j_{2}}}(\phi )$ .

This expression can then be manipulated into a sum of the irreducible representation characters:

$\chi _{j_{1}}(\phi )\chi _{j_{2}}(\phi )=(\sum _{\mathit {m_{2}=-j_{2}}}^{\mathit {j_{2}}}\;\;\epsilon ^{\mathit {m_{2}}})\;{\frac {\epsilon ^{\mathit {j_{1}+1}}-\epsilon ^{-{\mathit {j_{1}}}}}{\epsilon -1}}$

$=\sum _{\mathit {l=\left|j_{1}-j_{2}\right|}}^{\mathit {j_{1}+j_{2}}}\;\;{\frac {\epsilon ^{\mathit {l+1}}-\epsilon ^{\mathit {-l}}}{\epsilon -1}}$

Failed to parse (syntax error): {\displaystyle =\chi _{\mathit{j_{1}+j_{2}}}(\phi)\: +...\: +\:\chi _{\left |\mathit{j_{1}-j_{2}}\right |}(\phi)}

This shows that the product representation is reducible to a sum of the known irreducible representations:

$D_{\mathit {j_{1}}}\times D_{_{\mathit {j_{2}}}}\;=\;D_{\mathit {j_{1}+j_{2}}}+\;...\;+D_{\mathit {j_{1}-j_{2}}}.$

This is another way of aproach to the essential content of the angular momentum addition theorem.

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 Angular Momentum Addition by Characters
-Rotation matrices <math>e^{{\mathit{i}}{\vec{\omega }.\vec{J}}}</math> are <math>(2\mathit{j}+1)\times (2\mathit{j}+1)</math> matrix functions of rotating angles <math>\vec{\omega }</math> in some representation of spin <math>\mathit{j}</math>. To indicate more explicitly the representation we are in we write them as <math>D_{\mathit{j}}(\vec{\omega })</math>.
+Rotation matrices <math>e^{{\mathit{i}}{\vec{\omega }.\vec{J}}}</math> are <math>(2\mathit{j}+1)\times (2\mathit{j}+1)</math> matrix functions of rotating angles <math>\vec{\omega }</math> in some representation of spin <math>\mathit{j}</math>. To indicate more explicitly the representation we are in we write them as <math>D_{\mathit{j}}(\vec{\omega })</math>.Let us define the character by
+<math>\chi _{\mathit{j}}(\vec{\omega })=\mathit{tr}\; D_{\mathit{j}}(\vec{\omega})</math>
+For a rotation about the z-axis, the rotation matrix is diagonal
+<math>D_{\mathit{j}}(\phi\hat{z})=\; diag(e^{\mathit{ij}\phi}e^{\mathit{i(j-1)}\phi}...e^{-\mathit{ij}\phi})</math>
+and the character is easy to compute
+<math>\chi_{\mathit{j}}(\phi)=\sum_{\mathit{m=-j}}^{\mathit{j}}\; e^{\mathit{im\phi}}</math>
+<math>=\frac{\epsilon^{\mathit{j+1}}-\epsilon^{-\mathit{j}}}{\epsilon-1}\; \; \; where\; \; \epsilon=e^{\mathit{i\phi}}</math>
+<math>=\frac{sin(\mathit{j+\frac{1}{2})\phi}}{sin(\frac{\phi}{2})}</math>
+But any rotation may be brought to diagonal form by a similarity transform, so this is the most general character. It depends on the rotation angle, not the direction.
+If we tensor together the states <math> |\mathit{j_{1}m_{1}}\rangle </math> and <math>|\mathit{j_{2}m_{2}}\rangle</math>, they transform under the tensor product representation
+<math>D_{\mathit{j_{1}}}\times D_{\mathit{j_{2}}}</math>.These matrices have characters which are just products of the elementary characters.
+<math>D_{\mathit{j_{1}}}\times D_{\mathit{j_{2}}} :\; \; \; \chi_{}\mathit{j_{1}\times\mathit{j_{2}}}(\phi)=\chi _{\mathit{j_{1}}}(\phi)\chi _{\mathit{j_{2}}}(\phi)</math>.
+This expression can then be manipulated into a sum of the irreducible representation characters:
+<math>\chi_{j_{1}}(\phi)\chi_{j_{2}}(\phi)=(\sum_{\mathit{m_{2}=-j_{2}}}^{\mathit{j_{2}}}\; \; \epsilon^{\mathit{m_{2}}})\; \frac{\epsilon^{\mathit{j_{1}+1}}-\epsilon^{-\mathit{j_{1}}}}{\epsilon-1}
+</math>
+<math>=\sum_{\mathit{l=\left | j_{1}-j_{2} \right |}}^{\mathit{j_{1}+j_{2}}}\; \; \frac{\epsilon ^{\mathit{l+1}}-\epsilon^{\mathit{-l}}}{\epsilon -1}</math>
+<math>=\chi _{\mathit{j_{1}+j_{2}}}(\phi)\: +...\: +\:\chi _{\left |\mathit{j_{1}-j_{2}}\right |}(\phi)</math>
+This shows that the product representation is reducible to a sum of the known irreducible representations:
+<math>D_{\mathit{j_{1}}}\times D_{_{\mathit{j_{2}}}}\; =\; D_{\mathit{j_{1}+j_{2}}}+\; ...\; +D_{\mathit{j_{1}-j_{2}}}.</math>
+This is another way of aproach to the essential content of the angular momentum addition theorem.

Phy5646/character: Difference between revisions

Latest revision as of 20:40, 25 April 2010

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