194 research outputs found
Boundary between Hadron and Quark/Gluon Structure of Nuclei
We show that the boundary between quark-dominated and hadron-dominated
regions of nuclear structure may be blurred by multi-nucleon quark clusters
arising from color percolation. Recent experiments supporting partial
percolation in cold nuclei and full percolation in hot/dense nuclear matter
include: deep inelastic lepton-nucleus scattering, relativistic heavy-ion
collisions and the binding energy in .Comment: 10 pages, 4 figures; added references; improved figures; fixed a typo
(wrong sign in Eqn 6); Fixed typos in Equation 2; updated reference
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"
J/ production and suppression in nuclear collisions
In terms of a new QCD factorization formula for J/ production, we
calculate the J/ suppression in nuclear collisions by including the
multiple scattering between the pre-J/ partonic states and the nuclear
medium. We find agreement with all data on J/ suppression in
hadron-nucleus and nucleus-nucleus collisions, except a couple of points (the
``second drop'') at the highest bins of the new NA50 data.Comment: Latex, 4 pages, to appear in the proceedings of Quark Matter 200
Hamiltonian, Path Integral and BRST Formulations of Large N Scalar on the Light-Front and Spontaneous Symmetry Breaking
Recently Grinstein, Jora, and Polosa have studied a theory of large-
scalar quantum chromodynamics in one-space one-time dimension. This theory
admits a Bethe-Salpeter equation describing the discrete spectrum of
quark-antiquark bound states. They consider gauge fields in the adjoint
representation of and scalar fields in the fundamental representation.
The theory is asymptotically free and linearly confining. The theory could
possibly provide a good field theoretic framework for the description of a
large class of diquark-antidiquark (tetra-quark) states. Recently we have
studied the light-front quantization of this theory without a Higgs potential.
In the present work, we study the light-front Hamiltonian, path integral and
BRST formulations of the theory in the presence of a Higgs potential. The
light-front theory is seen to be gauge-invariant, possessing a set of
first-class constraints. The explicit occurrence of spontaneous symmetry
breaking in the theory is shown in unitary gauge as well as in the light-front
't Hooft gauge.Comment: Accepted for publication in Eur. Phys. J.
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