Magnetic structure of few-nucleon systems at high momentum transfers in a approach

Abstract

The five low-energy constants (LECs) in the electromagnetic current derived in chiral effective field theory () up to one loop are determined by a simultaneous fit to the A\,=\,2--3 nuclei magnetic moments and to the deuteron magnetic form factor and threshold electrodisintegration at backward angles over a wide range of momentum transfers. The resulting parametrization then yields predictions for the 3He/3H magnetic form factors in excellent accord with the experimental values for momentum transfers ranging up to ≈ 0.8 GeV/c, beyond the expected regime of validity of the approach. The calculations are based on last-generation two-nucleon interactions including high orders in the chiral expansion and derived by Entem, Macheleidt, and Nosyk [Phys.\ Rev.\ C 96, 024004 (2017)] and by Piarulli et al. [Phys.\ Rev.\ C 94, 054007 (2016)], using different formulations. In the A\,=\,3 calculations, (chiral) three-nucleon interactions are also accounted for. The model dependence resulting from these different formulations of the interactions is found to be mild for momentum transfer below ≈0.8 GeV/c. An analysis of the convergence of the chiral expansion is also provided.

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