198 research outputs found
Meson elastic and transition form factors
The Dyson-Schwinger equations of QCD, truncated to ladder-rainbow level, are
used to calculate meson form factors in impulse approximation. The infrared
strength of the ladder-rainbow kernel is described by two parameters fitted to
the chiral condensate and f_pi; the ultraviolet behavior is fixed by the QCD
running coupling. This obtained elastic form factors F_pi(Q^2) and F_K(Q^2)
agree well with the available data. We also calculate the rho to pi gamma and
K* to K gamma transition form factors, which are useful for meson-exchange
models.Comment: 6 pages, contribution to the JLab workshop Exclusive processes at
high-t, May 200
Electromagnetic properties of diquarks
Diquark correlations play an important role in hadron physics. The properties
of diquarks can be obtained from the corresponding bound state equation. Using
a model for the effective quark-quark interaction that has proved successful in
the light meson sector, we solve the scalar diquark Bethe-Salpeter equations
and use the obtained Bethe-Salpeter amplitudes to compute the diquarks'
electromagnetic form factors. The scalar ud diquark charge radius is about 8%
larger than the pion charge radius, indicating that these diquarks are somewhat
larger in size than the corresponding mesons. We also provide analytic fits for
the form factor over a moderate range in Q^2, which may be useful, for example,
in building quark-diquark models of nucleons.Comment: 11 pages, 3 .eps figures, minor corrections in table and figure, no
change in conclusion
Quarkonium as relativistic bound state on the light front
We study charmonium and bottomonium as relativistic bound states in a
light-front quantized Hamiltonian formalism. The effective Hamiltonian is based
on light-front holography. We use a recently proposed longitudinal confinement
to complete the soft-wall holographic potential for the heavy flavors. The spin
structure is generated from the one-gluon exchange interaction with a running
coupling. The adoption of asymptotic freedom improves the spectroscopy compared
with previous light-front results. Within this model, we compute the mass
spectroscopy, decay constants and the r.m.s. radii. We also present a detailed
study of the obtained light-front wave functions and use the wave functions to
compute the light-cone distributions, specifically the distribution amplitudes
and parton distribution functions. Overall, our model provides a reasonable
description of the heavy quarkonia.Comment: 28 pages, 17 figures, 5 tables. Supplemental Materials are provided
in the source file under "Other formats" (see also "Ancillary files"
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