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In [[quantum electrodynamics]], the '''vertex function''' describes the coupling between a photon and an electron beyond the leading order of [[perturbation theory (quantum mechanics)| perturbation theory]]. In particular, it is the [[one particle irreducible correlation function]] involving the [[fermion]] <math>\psi~</math>, the antifermion <math>\bar{\psi}</math>, and the [[vector potential]] '''A'''. | |||
==Definition== | |||
The vertex function Γ<sup>μ</sup> can be defined in terms of a [[functional derivative]] of the [[effective action]] S<sub>eff</sub> as | |||
:<math>\Gamma^\mu = -{1\over e}{\delta^3 S_{\mathrm{eff}}\over \delta \bar{\psi} \delta \psi \delta A_\mu}</math> | |||
[[Image:vertex_correction.svg|thumb|The one-loop correction to the vertex function. This is the dominant contribution to the anomalous magnetic moment of the electron.]] | |||
The dominant (and classical) contribution to Γ<sup>μ</sup> is the [[gamma matrix]] γ<sup>μ</sup>, which explains the choice of the letter. The vertex function is constrained by the symmetries of quantum electrodynamics — [[Lorentz invariance]]; [[gauge invariance]] or the [[Photon polarization| transversality]] of the photon, as expressed by the [[Ward identity]]; and invariance under [[Parity (physics)| parity]] — to take the following form: | |||
:<math> \Gamma^\mu = \gamma^\mu F_1(q^2) + \frac{i \sigma^{\mu\nu} q_{\nu}}{2 m} F_2(q^2) </math> | |||
where <math> \sigma^{\mu\nu} = (i/2) [\gamma^{\mu}, \gamma^{\nu}] </math>, <math> q_{\nu} </math> is the incoming four-momentum of the external photon (on the right-hand side of the figure), and F<sub>1</sub>(q<sup>2</sup>) and F<sub>2</sub>(q<sup>2</sup>) are ''form factors'' that depend only on the momentum transfer q<sup>2</sup>. At tree level (or leading order), F<sub>1</sub>(q<sup>2</sup>) = 1 and F<sub>2</sub>(q<sup>2</sup>) = 0. Beyond leading order, the corrections to F<sub>1</sub>(0) are exactly canceled by the [[wave function renormalization]] of the incoming and outgoing electron lines according to the [[Ward-Takahashi identity]]. The form factor F<sub>2</sub>(0) corresponds to the [[anomalous magnetic moment]] ''a'' of the fermion, defined in terms of the [[Landé g-factor]] as: | |||
:<math> a = \frac{g-2}{2} = F_2(0) </math> | |||
==References== | |||
*Michael E. Peskin and Daniel V. Schroeder, ''An Introduction to Quantum Field Theory'', Addison-Wesley, Reading, 1995. | |||
{{QED}} | |||
[[Category:Quantum electrodynamics]] | |||
[[Category:Quantum field theory]] | |||
{{quantum-stub}} | |||
Revision as of 05:01, 16 January 2014
In quantum electrodynamics, the vertex function describes the coupling between a photon and an electron beyond the leading order of perturbation theory. In particular, it is the one particle irreducible correlation function involving the fermion , the antifermion , and the vector potential A.
Definition
The vertex function Γμ can be defined in terms of a functional derivative of the effective action Seff as
The dominant (and classical) contribution to Γμ is the gamma matrix γμ, which explains the choice of the letter. The vertex function is constrained by the symmetries of quantum electrodynamics — Lorentz invariance; gauge invariance or the transversality of the photon, as expressed by the Ward identity; and invariance under parity — to take the following form:
where , is the incoming four-momentum of the external photon (on the right-hand side of the figure), and F1(q2) and F2(q2) are form factors that depend only on the momentum transfer q2. At tree level (or leading order), F1(q2) = 1 and F2(q2) = 0. Beyond leading order, the corrections to F1(0) are exactly canceled by the wave function renormalization of the incoming and outgoing electron lines according to the Ward-Takahashi identity. The form factor F2(0) corresponds to the anomalous magnetic moment a of the fermion, defined in terms of the Landé g-factor as:
![{\displaystyle \sigma ^{\mu \nu }=(i/2)[\gamma ^{\mu },\gamma ^{\nu }]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/5f420e36cf319388eb48505f5c2caa2c8864db36)
References
- Michael E. Peskin and Daniel V. Schroeder, An Introduction to Quantum Field Theory, Addison-Wesley, Reading, 1995.