Neutron Form Factors from Inelastic Electron-Deuteron Scattering

We perform a global analysis of the experimental data of the electromagnetic nucleon form factors, in space-like and time-like regions. We give the expressions of the observables in annihilation processes, such as p + p → ℓ + + ℓ − , ℓ = e or µ, in terms of form factors. We discuss some of the phenomenological models proposed in the literature for the space-like region, and consider their analytical continuation to the time-like region. After determining the parameters through a fit on the available data, we give predictions for the observables which will be experimentally accessible with large statistics, polarized annihilation reactions.

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“…[35,36,38,41,44] as data of much better precision were, later, available, in the same Q 2 range. The data in the TL region are drawn in In Fig.…”

Section: Resultsmentioning

confidence: 99%

Nucleon electromagnetic form factors and polarization observables in space-like and time-like regions

et al. 2005

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“…with g(x, z) ∈ U(N f ) which tends to constants as z → ±∞, 15) and hence keeps the boundary condition (2.12). In fact, under this local gauge transformation, the pion field transforms as…”

Section: Conserved Current Of Local Gauge Symmetrymentioning

confidence: 99%

Chiral currents and static properties of nucleons in holographic QCD

2008

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We analyze static properties of nucleons in the two flavor holographic QCD model of Sakai and Sugimoto described effectively by a five-dimensional U(2) YangMills theory with the Chern-Simons term on a curved background. The baryons are represented in this model as a soliton, which at a time slice is approximately the BPST instanton with a fixed size. First, we construct a chiral current in four dimensions from the Noether current of local gauge transformations which are non-vanishing on the boundaries of the extra dimension. We examine this chiral current for nucleons with quantized collective coordinates to compute their charge distribution, charge radii, magnetic moments and axial vector coupling. Most of the results are better close to the experimental values than in the Skyrme model. We discuss the problems of our chiral current; non-uniqueness of the local gauge transformation for defining the current, and its

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“…In an early experiment Hughes et al [Hug65] performed a Rosenbluth separation of quasi elastic d(e, e ′ ) cross sections in the range Q 2 = 0.04 to 1.17 GeV 2 ; they observed non-zero values of G En only below 0.2 GeV 2 2 The isoscalar (F S i ) and isovector (F V i ) Dirac (i = 1) and Pauli (i = 2) FFs are usually defined from the corresponding proton and neutron FFs as : played in Fig. 9, to be compared with the proton data from the same period in Fig.…”

Section: Neutron Magnetic Form Factor Measurementsmentioning

confidence: 99%

Nucleon electromagnetic form factors

Perdrisat

Punjabi

Vanderhaeghen

2007

Progress in Particle and Nuclear Physics

470

583

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There has been much activity in the measurement of the elastic electromagnetic proton and neutron form factors in the last decade, and the quality of the data has been greatly improved by performing double polarization experiments, in comparison with previous unpolarized data. Here we review the experimental data base in view of the new results for the proton, and neutron, obtained at MIT-Bates, MAMI, and JLab. The rapid evolution of phenomenological models triggered by these high-precision experiments will be discussed, including the recent progress in the determination of the valence quark generalized parton distributions of the nucleon, as well as the steady rate of improvements made in the lattice QCD calculations.

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Neutron Form Factors from Inelastic Electron-Deuteron Scattering

Cited by 146 publications

References 22 publications

Nucleon electromagnetic form factors and polarization observables in space-like and time-like regions

Nucleon electromagnetic form factors and polarization observables in space-like and time-like regions

Chiral currents and static properties of nucleons in holographic QCD

Nucleon electromagnetic form factors

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