Nucleon form factors in dispersively improved Chiral Effective Field Theory II: Electromagnetic form factors

Abstract

We study the nucleon electromagnetic form factors (EM FFs) using a recently developed method combining Chiral Effective Field Theory () and dispersion analysis. The spectral functions on the two-pion cut at t > 4 Mπ2 are constructed using the elastic unitarity relation and an N/D representation. is used to calculate the real functions J1 (t) = f1(t)/Fπ(t) (ratios of the complex ππ → N N partial-wave amplitudes and the timelike pion FF), which are free of ππ rescattering. Rescattering effects are included through the empirical timelike pion FF |Fπ(t)|2. The method allows us to compute the isovector EM spectral functions up to t 1 GeV2 with controlled accuracy (LO, NLO, and partial N2LO). With the spectral functions we calculate the isovector nucleon EM FFs and their derivatives at t = 0 (EM radii, moments) using subtracted dispersion relations. We predict the values of higher FF derivatives with minimal uncertainties and explain their collective behavior. We estimate the individual proton and neutron FFs by adding an empirical parametrization of the isoscalar sector. Excellent agreement with the present low-Q2 FF data is achieved up to 0.5 GeV2 for GE, and up to 0.2 GeV2 for GM. Our results can be used to guide the analysis of low-Q2 elastic scattering data and the extraction of the proton charge radius.