Hadron structure and the limitations of phenomenological models in electromagnetic reactions

J. H. Koch, V. Pascalutsa, S. Scherer

Published 2001-08-17Version 1

The description of electromagnetic reactions at intermediate energies, such as pion electroproduction or (virtual) Compton scattering, traditionally starts from covariant tree-level Feynman diagrams (Born or pole terms). Internal hadron structure is included by means of (on-shell) form factors in the vertices while free propagators are used. To overcome problems with gauge invariance, simple prescriptions such as choosing $F_1^V (q^2) = F_{\pi} (q^2)$ in pion electroproduction or the ``minimal substitution'' are used. We discuss the limitations of such approaches by comparing to the most general structure of electromagnetic vertices and propagators for pions and nucleons. The recipes to enforce gauge invariance are critically examined and contrasted with the exact treatment. The interplay between off-shell effects and irreducible ``contact'' terms is demonstrated for real Compton scattering on a pion. The need for a consistent microscopic treatment of reaction amplitudes is stressed. Shortcomings of minimal substitution are illustrated through an example in the framework of chiral perturbation theory.