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We present results for the isovector electromagnetic form factors of the nucleon computed on the coordinated lattice simulations ensembles with N₅=2+1 flavors of O (a) -improved Wilson fermions and an O (a) -improved vector current. The analysis includes ensembles with four lattice spacings and pion masses ranging from 130 up to 350 MeV and mainly targets the low-Q^2 region. In order to remove any bias from unsuppressed excited-state contributions, we investigate several source-sink separations between 1. 0 and 1. 5 fm and apply the summation method as well as explicit two-state fits. The chiral interpolation is performed by applying covariant chiral perturbation theory including vector mesons directly to our form factor data, thus avoiding an auxiliary parametrization of the Q^2 dependence. At the physical point, we obtain =4. 71 (11) ₒₓ₀ₓ (13) ₒₘₒ for the nucleon isovector magnetic moment, in good agreement with the experimental value and ⟨r₌^2⟩=0. 661 (30) ₒₓ₀ₓ (11) ₒₘₒ fm^2 for the corresponding square radius, again in good agreement with the value inferred from the ep-scattering determination Bernauer et al. , Phys. Rev. Lett. 105, 242001 (2010) of the proton radius. Our estimate for the isovector electric charge radius, ⟨r₄^2⟩=0. 800 (25) ₒₓ₀ₓ (22) ₒₘₒ fm^2, however, is in slight tension with the larger value inferred from the aforementioned ep-scattering data, while being in agreement with the value derived from the 2018 CODATA average for the proton charge radius.
Djukanovic et al. (Fri,) studied this question.