Phy5645/Plane Rotator: Difference between revisions

Latest revision as of 13:41, 18 January 2014

(a) $A\!$ can be determined from the normalization condition,

$1=\int _{-\pi }^{\pi }d\phi \,|\psi (\phi )|^{2}=A^{2}\int _{-\pi }^{\pi }d\phi \,\sin ^{4}{\phi }=A^{2}\cdot {\frac {3\pi }{4}}.$

Therefore, $A={\frac {2}{\sqrt {3\pi }}}.$

(b) The probability to measure the angular momentum to be $\hbar m$ is

$P_{m}=|\langle m|\psi \rangle |^{2}=\left|{\frac {1}{\sqrt {2\pi }}}\int _{-\pi }^{\pi }d\phi \,e^{im\phi }\psi (\phi )\right|^{2}={\tfrac {2}{3}}\delta _{m,0}+{\tfrac {1}{6}}(\delta _{m,2}+\delta _{m,-2})$

Therefore the probability of measuring $L_{z}=0\!$ is ${\tfrac {2}{3}},$ that of measuring $L_{z}=2\hbar \!$ is ${\tfrac {1}{6}}$ , and that of measuring $L_{z}=-2\hbar$ is also ${\tfrac {1}{6}}.$ The probability of measuring any other value is zero.

(c)

$\langle {\hat {L}}_{z}\rangle ={\frac {4}{3\pi }}\int _{-\pi }^{\pi }d\phi \,\sin ^{2}{\phi }\left(-i\hbar {\frac {d}{d\phi }}\sin ^{2}{\phi }\right)=-{\frac {8}{3\pi }}i\hbar \int _{-\pi }^{\pi }d\phi \,\sin ^{3}{\phi }\cos {\phi }=0$

$\langle {\hat {L}}_{z}^{2}\rangle ={\frac {4}{3\pi }}\int _{-\pi }^{\pi }d\phi \,\sin ^{2}{\phi }\left(-\hbar ^{2}{\frac {d^{2}}{d\phi ^{2}}}\sin ^{2}{\phi }\right)=-{\frac {8}{3\pi }}\hbar ^{2}\int _{-\pi }^{\pi }d\phi \,\sin ^{2}{\phi }(1-2\sin ^{2}{\phi })={\tfrac {4}{3}}\hbar ^{2}$

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@@ Line 1: / Line 1: @@
-'''(a)''' <math>A\!</math> can be determined from the normalization condition:
+'''(a)''' <math>A\!</math> can be determined from the normalization condition,
-<math>1=\int_{-\pi}^{\pi}d\phi\,|\psi(\phi)|^2=A^2 \int_{-\pi}^{\pi}d\phi\,\sin^2{2\phi} = A^23\pi/4  </math>
+<math>1=\int_{-\pi}^{\pi}d\phi\,|\psi(\phi)|^2=A^2 \int_{-\pi}^{\pi}d\phi\,\sin^4{\phi} = A^2\cdot\frac{3\pi}{4}.</math>
-Then, we could get <math> A= \frac{2}{\sqrt{3 \pi}} </math>
+Therefore, <math>A=\frac{2}{\sqrt{3\pi}}.</math>
-b) The probability to measure the angular momentum to be <math> \hbar m </math> is
+'''(b)''' The probability to measure the angular momentum to be <math> \hbar m </math> is
-<math> P_m = |<\psi_m|\psi>|^2 = |\int_{-\pi}^{\pi}d\phi \frac {e^{-im\phi}}{\sqrt {2\pi}} \psi(\phi)|^2 = \frac {2}{3} \delta_{m,0} + \frac {1}{6}(\delta_{m,2}+\delta_{m,-2}) </math>
+<math> P_m = |\langle m|\psi\rangle|^2 = \left |\frac{1}{\sqrt{2\pi}}\int_{-\pi}^{\pi}d\phi\,e^{im\phi}\psi(\phi)\right |^2 = \tfrac{2}{3} \delta_{m,0}+\tfrac {1}{6}(\delta_{m,2}+\delta_{m,-2}) </math>
-Therefore the probability to measure <math> L_z = 0 </math> is <math>\frac {2}{3} </math> , the probability to measure <math> L_z = 2 </math> is <math>\frac {1}{6} </math> , and the probability to measure <math> L_z = -2 </math> is </math> is <math>\frac {1}{6} </math> . The probability to measure any other value is zero.
+Therefore the probability of measuring <math>L_z = 0\!</math> is <math>\tfrac{2}{3},</math> that of measuring <math>L_z = 2\hbar\!</math> is <math>\tfrac{1}{6}</math>, and that of measuring <math> L_z = -2\hbar</math> is also <math>\tfrac {1}{6}.</math>  The probability of measuring any other value is zero.
-c) <math> <L_z>=0 </math>
+'''(c)'''
-<math> <L^2>=\frac{4\hbar}{3} </math>
+<math>\langle\hat{L}_z\rangle=\frac{4}{3\pi}\int_{-\pi}^{\pi}d\phi\,\sin^2{\phi}\left (-i\hbar\frac{d}{d\phi}\sin^2{\phi}\right )=-\frac{8}{3\pi}i\hbar\int_{-\pi}^{\pi}d\phi\,\sin^3{\phi}\cos{\phi}=0 </math>
-Back to [[Orbital Angular Momentum Eigenfunctions]]
+<math>\langle\hat{L}_z^2\rangle=\frac{4}{3\pi}\int_{-\pi}^{\pi}d\phi\,\sin^2{\phi}\left (-\hbar^2\frac{d^2}{d\phi^2}\sin^2{\phi}\right )=-\frac{8}{3\pi}\hbar^2\int_{-\pi}^{\pi}d\phi\,\sin^2{\phi}(1-2\sin^2{\phi})=\tfrac{4}{3}\hbar^2</math>
+Back to [[Orbital Angular Momentum Eigenfunctions#Problems|Orbital Angular Momentum Eigenfunctions]]

Phy5645/Plane Rotator: Difference between revisions

Latest revision as of 13:41, 18 January 2014

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