A Maximum-Entropy Method for Zero-Skewness Valence GPDs Constrained by Nucleon Electromagnetic Form Factors
Abstract
We formulate a reduced-profile maximum-entropy method (MEM) framework for constructing constrained zero-skewness valence-quark generalized parton distribution (GPD) transverse profiles from the four nucleon electromagnetic form factors F1p(t), F1n(t), F2p(t), and F2n(t). The form-factor sum rules fix only x-integrated moments of the GPDs; the forward limit of Hvq is fixed separately by the valence parton distribution functions, and the normalization of Evq by the flavor anomalous magnetic moments. These complementary constraints are combined through the ansatz Hvq(x,t)=qv(x)[t fHq(x)] and Evq(x,t)=evq(x)[t fEq(x)], where the positive profile functions encode the x-dependent transverse structure. Rather than attempting an unrestricted functional inversion, we use the entropy functional as a regularizing criterion on a low-dimensional positive profile manifold. In the numerical proof-of-concept calculation, a smooth elastic form-factor input and analytic forward distributions are adopted, together with the reduced form f(x)=0.05+(1-x)2(c0+c1x+c2x2), which suppresses local modes that elastic moments alone cannot constrain. Within this reduced ansatz, the resulting profiles reproduce the imposed elastic moment constraints, satisfy the forward normalizations after discrete-grid normalization, and give impact-parameter distributions with the expected transverse shrinkage at large x. The construction provides a controlled zero-skewness baseline for connecting elastic form-factor constraints to x-dependent transverse profiles, and it offers a stable starting point for future analyses incorporating empirical form-factor fits, modern PDF inputs, lattice-QCD generalized form factors, and hard exclusive observables.
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