33,659 research outputs found
Chiral symmetry breaking in QCD-like gauge theories with a confining propagator and dynamical gauge boson mass generation
We study chiral symmetry breaking in QCD-like gauge theories introducing a
confining effective propagator, as proposed recently by Cornwall, and
considering the effect of dynamical gauge boson mass generation. The effective
confining propagator has the form and we study the bifurcation
equation finding limits on below which a satisfactory fermion mass solution
is generated. Since the coupling constant and gauge boson propagator are damped
in the infrared, due to the presence of dynamically massive gauge bosons, the
major part of the chiral breaking is only due to the confining propagator. We
study the asymptotic behavior of the gap equation containing confinement and
massive gauge boson exchange, and find that the symmetry breaking can be
approximated at some extent by an effective four-fermion interaction generated
by the confining propagator. We compute some QCD chiral parameters as a
function of , finding values compatible with the experimental data. Within
this approach we expect that lattice simulations should not see large
differences between the confinement and chiral symmetry breaking scales
independent of the fermionic representation and we find a simple approximate
relation between the fermion condensate and dynamical mass for a given
representation as a function of the parameters appearing in the effective
confining propagator.Comment: 32 pages, 9 figures, new references added, matchs published versio
Chiral symmetry breaking with a confining propagator and dynamically massive gluons
Chiral symmetry breaking in QCD is studied introducing a confining effective
propagator, as proposed recently by Cornwall, and considering the effect of
dynamically massive gluons. The effective confining propagator has the form
and we study the bifurcation equation finding limits on the
parameter below which a satisfactory fermion mass solution is generated.
Since the coupling constant and gluon propagator are damped in the infrared,
due to the presence of a dynamical gluon mass, the major part of the chiral
breaking is only due to the confining propagator and related to the low
momentum region of the gap equation. We study the asymptotic behavior of the
gap equation containing this confinement effect and massive gluon exchange, and
find that the symmetry breaking can be approximated by an effective
four-fermion interaction generated by the confining propagator. We compute some
QCD chiral parameters as a function of , finding values compatible with the
experimental data. We find a simple approximate relation between the fermion
condensate and dynamical mass for a given representation as a function of the
parameters appearing in the effective confining propagator.Comment: 12 pages, 2 figures. Talk presented at the International Workshop on
QCD Green's Functions, Confinement, and Phenomenology - QCD-TNT II, September
05-09 2011, ECT* Trento, Italy; ANN.PHYS.(NY, 2011
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Algorithms for network piecewise-linear programs
In this paper a subarea of Piecewise-Linear Programming named network Piecewise-Linear Programming (NPLP) is discussed. Initially the problem formulation, main efinitins and related Concepts are presented. In the sequence of the paper, four specialized algorithms for NPLP, as well as the results of a preliminary computational study, are presented
Shape instabilities in vesicles: a phase-field model
A phase field model for dealing with shape instabilities in fluid membrane
vesicles is presented. This model takes into account the Canham-Helfrich
bending energy with spontaneous curvature. A dynamic equation for the
phase-field is also derived. With this model it is possible to see the vesicle
shape deformation dynamically, when some external agent instabilizes the
membrane, for instance, inducing an inhomogeneous spontaneous curvature. The
numerical scheme used is detailed and some stationary shapes are shown together
with a shape diagram for vesicles of spherical topology and no spontaneous
curvature, in agreement with known results
Geometric scaling in ultrahigh energy neutrinos and nonlinear perturbative QCD
It is shown that in ultrahigh energy inelastic neutrino-nucleon(nucleus)
scattering the cross sections for the boson-hadron(nucleus) reactions should
exhibit geometric scaling on the single variable tau_A =Q2/Q2_{sat,A}. The
dependence on energy and atomic number of the charged/neutral current cross
sections are encoded in the saturation momentum Q_{sat,A}. This fact allows an
analytical computation of the neutrino scattering on nucleon/nucleus at high
energies, providing a theoretical parameterization based on the scaling
property.Comment: 5 pages, 4 figure
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