Improved empirical parametrizations of the γ N (1232) and γ N N(1520) helicity amplitudes and the Siegert's theorem

Abstract

In the nucleon electroexcitation reactions, γ N R, where R is a nucleon resonance (N), the electric amplitude E, and the longitudinal amplitude S1/2, are related by E ω| q|S1/2, at the pseudo-threshold limit (| q| 0), where ω and | q| are respectively the energy and the magnitude of three-momentum of the photon. The previous relation is usually refereed as the Siegert's theorem. The form of the electric amplitude, defined in terms of the transverse amplitudes A1/2 and A3/2, and the explicit coefficients of the relation, depend on the angular momentum and parity (JP) of the resonance R. The Siegert's theorem is the consequence of the structure of the electromagnetic transition current, which induces constraints between the electromagnetic form factors in the pseudo-threshold limit. In the present work, we study the implications of the Siegert's theorem for the γ N (1232) and γ N N(1520) transitions. For the γ N N(1520) transition, in addition to the relation between electric amplitude and longitudinal amplitude, we obtain also a relation between the two transverse amplitudes: A1/2= A3/2 /3, at the pseudo-threshold. % The constraints at the pseudo-threshold are tested for the MAID2007 parametrizations of the reactions under discussion. New parametrizations for the amplitudes A1/2, A3/2 and S1/2, for the γ N (1232) and γ N N(1520) transitions, valid for small and large Q2, are proposed. The new parametrizations are consistent with both: the pseudo-threshold constraints (Siegert's theorem) and the empirical data.