Difference between revisions of "Forest Bhabha Scattering"
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Line 34: | Line 34: | ||
;The QED interaction Lagrangian is | ;The QED interaction Lagrangian is | ||
− | :<math>-eA_{\mu} \bar{\Psi} \gamma^{\mu} \ | + | :<math>-eA_{\mu} \bar{\Psi} \gamma^{\mu} \Psi</math> |
<math>\mathcal{M}_s = \,</math> | <math>\mathcal{M}_s = \,</math> |
Revision as of 16:31, 14 April 2012
Bhabha (electron -positron) Scattering
Bhabha scattering identifies the scatterng of an electron and positron (particle and anti-particle). There are two processes that can occur
1.) scattering via the exchange of a virtual photon
2.) annihilation in which the e+ and e- spend some time as a photon which then reconverts back to an e+e- pair
variables
Let:
- initial electron 4-momentum
- u_1 \equiv initial electron spinor
- p_2 \equiv final electron 4-momentum
- u_2 \equiv final electron spinor
- p_3 \equiv initial positron 4-momentum
- \bar{u}_3 \equiv initial positron spinor
- p_4 \equiv finial positron 4-momentum
- finial positron spinor
Matrix element for scattering
According to the Feynman RUles for QED:
the term
is used at the vertex to describe the Quantum electrodynamic interaction beetween the two spinor states entering the vertex and forming a photon which will "connect" this vertex with the next one.
- The QED interaction Lagrangian is
Matrix element for annihilation