51 research outputs found
Quark-meson coupling model with short-range quark-quark interactions
Short-range quark-quark correlations are introduced into the quark-meson
coupling (QMC) model phenomenologically. We study the effect of the
correlations on the structure of the nucleon in dense nuclear matter. With the
addition of correlations, the saturation curve for symmetric nuclear matter is
much improved at high density.Comment: 6 pages (including 4 figures), to be published in Prog. Theor. Phys.
(Kyoto) vol.105, no.2 (2001
Magnetic moments of the octet, low-lying charm, and low-lying bottom baryons in a nuclear medium
We study the magnetic moments of the octet, low-lying charm, and low-lying
bottom baryons with nonzero light quarks in symmetric nuclear matter. This is
the first study of estimating the medium modifications of magnetic moments for
these low-lying charm and bottom baryons.Comment: 13 pages, 8 figures (eps files
Self-consistent description of finite nuclei based on a relativistic quark model
Relativistic Hartree equations for spherical nuclei have been derived from a
relativistic quark model of the structure of bound nucleons which interact
through the (self-consistent) exchange of scalar () and vector
( and ) mesons. The coupling constants and the mass of the
-meson are determined from the properties of symmetric nuclear matter
and the rms charge radius in Ca. Calculated properties of static,
closed-shell nuclei from O to Pb are compared with experimental
data and with results of Quantum Hadrodynamics (QHD). The dependence of the
results on the nucleon size and the quark mass is investigated. Several
possible extensions of the model are also discussed.Comment: 37 pages, 17 postscript figures are included, uses epsfig.sty,
uuencoded Z-compressed .tar file (uufiles
Variation of hadron masses in finite nuclei
Using a self-consistent, Hartree description for both infinite nuclear matter
and finite nuclei based on a relativistic quark model (the quark-meson coupling
model), we investigate the variation of the masses of the non-strange vector
mesons, the hyperons and the nucleon in infinite nuclear matter and in finite
nuclei.Comment: 4 pages plus one ps file, to appear in Proc. of International
Symposium on Non-Nucleonic Degrees of Freedom Detected in Nucleus (NNDF '96)
at Osaka, Japa
and mesons in nuclear matter and nuclei
We present updated and extended results for the - and -nucleus
bound state energies, obtained by solving the Schr\"{o}dinger and Klein-Gordon
equations with complex optical potentials, for a wide range of nuclei. The
and nuclear potentials are obtained in the local density
approximation from the mass shift of these mesons in nuclear matter, which is
calculated within the quark-meson coupling model. Our results show that the
and mesons are expected to form mesic nuclei with all the nuclei
considered. However, the signal for the formation of the - and
-mesic nuclei may be difficult to identify experimentally due to
possible large widths.Comment: 11 pages, 4 figures, 6 table
Baryon Mass Extrapolation
Consideration of the analytical properties of pion-induced baryon
self-energies leads to new functional forms for the extrapolation of light
baryon masses. These functional forms reproduce the leading non-analytic
behavior of chiral perturbation theory, the correct heavy-quark limit and have
the advantage of containing information on the extended structure of hadrons.
The forms involve only three unknown parameters which may be optimized by
fitting to present lattice data. Recent dynamical fermion results from CP-PACS
and UK-QCD are extrapolated using these new functional forms. We also use these
functions to probe the limit of the chiral perturbative regime and shed light
on the applicability of chiral perturbation theory to the extrapolation of
present lattice QCD results.Comment: LATTICE99 (QCD Spectrum and Quark Masses
Chiral Corrections to Baryon Masses Calculated within Lattice QCD
Consideration of the analytic properties of pion-induced baryon self energies
leads to new functional forms for the extrapolation of light baryon masses.
These functional forms reproduce the leading non-analytic behavior of chiral
perturbation theory, the correct non-analytic behavior at the threshold
and the appropriate heavy-quark limit. They involve only three unknown
parameters, which may be obtained by fitting lattice QCD data. Recent dynamical
fermion results from CP-PACS and UKQCD are extrapolated using these new
functional forms. We also use these functions to probe the limit of
applicability of chiral perturbation theory.Comment: 4 pages, 2 figures, Contribution to the Proceedings of the 15th
Particles and Nuclei International Conference (PANIC 99), Uppsala, Sweden,
June 10-16, 199
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