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Position space method for the nucleon magnetic moment in lattice QCD

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arxiv 1605.07327 v2 pith:5AENJA36 submitted 2016-05-24 hep-lat

Position space method for the nucleon magnetic moment in lattice QCD

classification hep-lat
keywords magneticmomentumformfactorlatticemethodmomentdependence
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The extraction of the magnetic form factor of the nucleon at zero momentum transfer is usually performed by adopting a parametrization for its momentum dependence and fitting the results obtained at finite momenta. We present a position space method that allows us to remove the momentum prefactor in the form factor decomposition and hence compute the magnetic form factor directly at zero momentum without the need to assume a functional form for its momentum dependence. The method is explored on one ensemble using $N_f=2+1+1$ Wilson twisted mass fermions with a light quark mass corresponding to $M_\pi\approx373\mathrm{GeV}$ and a lattice spacing of $a\approx0.082\mathrm{fm}$. We obtain results for the isovector magnetic moment and for the proton and neutron magnetic moments. The value we find for the isovector magnetic moment is larger as compared to fitting the form factor at the discrete values of the lattice momentum transfers using a dipole Ansatz, bringing it closer to the experimental value.

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