Abstract
We produce the light-front wave functions (LFWFs) of the nucleon from a basis light-front approach in the leading Fock-sector representation. We solve for the mass eigenstates from a light-front effective Hamiltonian, which includes a confining potential adopted from light-front holography in the transverse direction, a longitudinal confinement, and a one-gluon exchange interaction with fixed coupling. We then employ the LFWFs to obtain the electromagnetic and axial form factors, the parton distribution functions (PDFs), and the generalized parton distribution functions for the nucleon. The electromagnetic and axial form factors of the proton agree with the experimental data, whereas the neutron form factors deviate somewhat from the experiments in the low-momentum transfer region. The unpolarized, the helicity, and the transversity valence quark PDFs, after QCD scale evolution, are fairly consistent with the global fits to the data at the relevant experimental scales. The helicity asymmetry for the down quark also agrees well with the measurements; however, the asymmetry for the up quark shows a deviation from the data, especially in the small $x$ region. We also find that the tensor charge agrees well with the extracted data and the lattice QCD predictions, while the axial charge is somewhat outside the experimental error bar. The electromagnetic radii of the protons, the magnetic radius of the neutron, and the axial radius are in excellent agreement with the measurements, while the neutron charge radius deviates from the experiment.
Highlights
One of the main goals in hadron physics is to understand how nucleons and other hadrons are built up from quarks and gluons
Our approach features an effective one-gluon exchange (OGE) interaction that is important for short distance physics and approximately describes the processes where valence quarks emit and absorb a gluon
According to the mass evolution in renormalization group theory, the dynamical OGE would generate contributions to the quark mass arising from higher momentum scales leading to a decrease in the quark mass from the gluon dynamics
Summary
One of the main goals in hadron physics is to understand how nucleons and other hadrons are built up from quarks and gluons. From deep inelastic scattering (DIS) processes one can extract the parton distribution functions (PDFs), which encode the nonperturbative structure of the nucleon in terms of the distribution of longitudinal momentum carried by the quarks and gluons as its constituents. Both the observables, FFs and PDFs, have taught us a great deal about the nucleon, but these quantities do not provide full three-dimensional structural information of the nucleon.
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