|
|
| Line 4: |
Line 4: |
| | | | |
| | Let's begin with a general amplitude for the two-body decay of a state with angular momentum quantum numbers ''J'',''m''. Specifically, we want to know the amplitude of this state having daughter 1 with trajectory <math>\Omega=(\phi,\theta)</math>. | | Let's begin with a general amplitude for the two-body decay of a state with angular momentum quantum numbers ''J'',''m''. Specifically, we want to know the amplitude of this state having daughter 1 with trajectory <math>\Omega=(\phi,\theta)</math>. |
| − | We can also describe the angular momentum between the daughters as being ''L'' and spin sum as ''s''. Alternatively, we will label the daughters as having helicities of <math>\lambda_1</math> and <math>\lambda_2</math> or direction of decay (specified by daughter 1) of | + | We can also describe the angular momentum between the daughters as being ''L'' and spin sum as ''s''. Alternatively, we will label the daughters as having helicities of <math>\lambda_1</math> and <math>\lambda_2</math> - projections on the direction of decay (specified by daughter 1) of |
| | | | |
| | <table> | | <table> |
| Line 47: |
Line 47: |
| | | | |
| | </table> | | </table> |
| − |
| |
| | | | |
| | === Isospin Projections === | | === Isospin Projections === |
Revision as of 16:12, 1 August 2011
General Relations
Angular Distribution of Two-Body Decay
Let's begin with a general amplitude for the two-body decay of a state with angular momentum quantum numbers J,m. Specifically, we want to know the amplitude of this state having daughter 1 with trajectory 
.
We can also describe the angular momentum between the daughters as being L and spin sum as s. Alternatively, we will label the daughters as having helicities of 
and Failed to parse (MathML with SVG or PNG fallback (recommended for modern browsers and accessibility tools): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle \lambda_2}
- projections on the direction of decay (specified by daughter 1) of
 |
simple insertion of complete sets of states for recoupling
|
![{\displaystyle =\sum _{L,S}\left[{\sqrt {\frac {2J+1}{4\pi }}}D_{m\lambda }^{J*}(\Omega ,0)\right]\left[{\sqrt {\frac {2L+1}{2J+1}}}\left({\begin{array}{cc|c}L&S&J\\0&\lambda &\lambda \end{array}}\right)\left({\begin{array}{cc|c}S_{1}&S_{2}&S\\\lambda _{1}&-\lambda _{2}&\lambda \end{array}}\right)\right]a_{LS}^{J}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/a93b86e837aee85c12249ab0f791a8c2693e53e6) |
Substitution of each bra-ket with their respective formulae.
Note that in the event of one daughter being spin-less, the second
Clebsch-Gordan coefficient is 1
|
Isospin Projections
One must also take into account the various ways isospin of daughters can add up to the isospin quantum numbers of the parent, requiring a term:
where a=1 and b=2, referring to the daughter number. Because an even-symmetric angular wave function (i.e. L=0,2...) imply that 180 degree rotation is equivalent to reversal of daughter identities, a,b becoming b,a on must write down the symmetrized expression:
![{\displaystyle C(L)={\frac {1}{\sqrt {2}}}\left[C^{a,b}+(-1)^{L}C^{b,a}\right]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/4b6552f1762b7ab2260cedf2da6cc0b67fe3d16c)
Application
![{\displaystyle \langle \Omega _{X}0\lambda _{b_{1}}|U_{X}|J_{X}m_{X}\rangle =\sum _{L_{X}}\left[{\sqrt {\frac {2J_{X}+1}{4\pi }}}D_{m_{X}\lambda _{b_{1}}}^{J_{X}*}(\Omega _{X},0)\right]\left[{\sqrt {\frac {2L_{X}+1}{2J_{X}+1}}}\left({\begin{array}{cc|c}L_{X}&1&J_{X}\\0&\lambda _{b_{1}}&\lambda _{b_{1}}\end{array}}\right)\right]a_{L_{X}}^{J_{X}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/cad672ca5c561044c1b437d8d89af02651ae0a69)
![{\displaystyle \langle \Omega _{b_{1}}0\lambda _{\omega }|U_{b_{1}}|1,m_{b_{1}}=\lambda _{b_{1}}\rangle =\sum _{L_{b_{1}}}\left[{\sqrt {\frac {2J_{b_{1}}+1}{4\pi }}}D_{m_{b_{1}}=\lambda _{b_{1}}\lambda _{\omega }}^{1*}(\Omega _{b_{1}},0)\right]\left[{\sqrt {\frac {2L_{b_{1}}+1}{2J_{b_{1}}+1}}}\left({\begin{array}{cc|c}L_{b_{1}}&1&1\\0&\lambda _{\omega }&\lambda _{\omega }\end{array}}\right)\right]b_{L_{b_{1}}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/6aea4d4ccab5c0cc9ef931eb1fc4a558493c503c)
![{\displaystyle \langle \Omega _{\omega }0\lambda _{\rho }|U_{\omega }|1,m_{\omega }=\lambda _{\omega }\rangle =\sum _{L_{\omega }J_{\rho }}\left[{\sqrt {\frac {2J_{\omega }+1}{4\pi }}}D_{m_{\omega }=\lambda _{\omega }\lambda _{\rho }}^{1*}(\Omega _{\omega },0)\right]\left[{\sqrt {\frac {2L_{\omega }+1}{2J_{\omega }+1}}}\left({\begin{array}{cc|c}L_{\omega }&1&1\\0&\lambda _{\rho }&\lambda _{\rho }\end{array}}\right)\right]c_{L_{\omega }J_{\rho }}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/08bb5334fb417cbd67f2e356cc0fbdc5b41db623)
![{\displaystyle \langle \Omega _{\rho }0\lambda _{\rho }|U_{\rho }|J_{\rho },m_{\rho }=\lambda _{\rho }\rangle =\sum _{L_{\rho }}\left[{\sqrt {\frac {2J_{\rho }+1}{4\pi }}}D_{m_{\rho }0}^{J_{\rho }*}(\Omega _{\rho },0)\right]\left[{\sqrt {\frac {2L_{\rho }+1}{2J_{\rho }+1}}}\left({\begin{array}{cc|c}L_{\rho }&0&J_{\rho }\\0&0&0\end{array}}\right)\right]d_{L_{\rho }}=\sum _{L_{\rho }}{\sqrt {\frac {2L_{\rho }+1}{4\pi }}}Y_{m_{\rho }}^{J_{\rho }*}(\Omega _{\rho })d_{L_{\rho }}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/96a49444ada8e1ec8e774bda860fb78917fa3392)
