145 research outputs found
Heavy-quarks in the QGP: study of medium effects through euclidean propagators and spectral functions
The heavy-quark spectral function in a hot plasma is reconstructed from the
corresponding euclidean propagator. The latter is evaluated through a
path-integral simulation. A weak-coupling calculation is also performed,
allowing to interpret the qualitative behavior of the spectral function in
terms of quite general physical processes.Comment: 4 pages, 3 figures - To appear in the conference proceedings for
Quark Matter 2009, March 30 - April 4, Knoxville, Tennesse
Medium-induced color flow softens hadronization
Medium-induced parton energy loss, resulting from gluon exchanges between the
QCD matter and partonic projectiles, is expected to underly the strong
suppression of jets and high- hadron spectra observed in
ultra-relativistic heavy ion collisions. Here, we present the first
color-differential calculation of parton energy loss. We find that color
exchange between medium and projectile enhances the invariant mass of energetic
color singlet clusters in the parton shower by a parametrically large factor
proportional to the square root of the projectile energy. This effect is seen
in more than half of the most energetic color-singlet fragments of
medium-modified parton branchings. Applying a standard cluster hadronization
model, we find that it leads to a characteristic additional softening of
hadronic spectra. A fair description of the nuclear modification factor
measured at the LHC may then be obtained for relatively low momentum transfers
from the medium
A path integral for heavy-quarks in a hot plasma
We propose a model for the propagation of a heavy-quark in a hot plasma, to
be viewed as a first step towards a full description of the dynamics of heavy
quark systems in a quark-gluon plasma, including bound state formation. The
heavy quark is treated as a non relativistic particle interacting with a
fluctuating field, whose correlator is determined by a hard thermal loop
approximation. This approximation, which concerns only the medium in which the
heavy quark propagates, is the only one that is made, and it can be improved.
The dynamics of the heavy quark is given exactly by a quantum mechanical path
integral that is calculated in this paper in the Euclidean space-time using
numerical Monte Carlo techniques. The spectral function of the heavy quark in
the medium is then reconstructed using a Maximum Entropy Method. The path
integral is also evaluated exactly in the case where the mass of the heavy
quark is infinite; one then recovers known results concerning the complex
optical potential that controls the long time behavior of the heavy quark. The
heavy quark correlator and its spectral function is also calculated
semi-analytically at the one-loop order, which allows for a detailed
description of the coupling between the heavy quark and the plasma collective
modes
Heavy flavours in heavy-ion collisions: quenching, flow and correlations
We present results for the quenching, elliptic flow and azimuthal
correlations of heavy flavour particles in high-energy nucleus-nucleus
collisions obtained through the POWLANG transport setup, developed in the past
to study the propagation of heavy quarks in the Quark-Gluon Plasma and here
extended to include a modeling of their hadronization in the presence of a
medium. Hadronization is described as occurring via the fragmentation of
strings with endpoints given by the heavy (anti-)quark Q(Qbar) and a thermal
parton qbar(q) from the medium. The flow of the light quarks is shown to affect
significantly the R_AA and v_2 of the final D mesons, leading to a better
agreement with the experimental data. The approach allows also predictions for
the angular correlation between heavy-flavour hadrons (or their decay
electrons) and the charged particles produced in the fragmentation of the
heavy-quark strings
Lattice QCD-based equations of state at vanishing net-baryon density
We present realistic equations of state for QCD matter at vanishing
net-baryon density which embed recent lattice QCD results at high temperatures
combined with a hadron resonance gas model in the low-temperature, confined
phase. In the latter, we allow an implementation of partial chemical
equilibrium, in which particle ratios are fixed at the chemical freeze-out, so
that a description closer to the experimental situation is possible. Given the
present uncertainty in the determination of the chemical freeze-out temperature
from first-principle lattice QCD calculations, we consider different values
within the expected range. The corresponding equations of state can be applied
in the hydrodynamic modeling of relativistic heavy-ion collisions at the LHC
and at the highest RHIC beam energies. Suitable parametrizations of our results
as functions of the energy density are also provided.Comment: Updated journal version with refined EoS-parametrization. July 2014.
8 pp. 4 figs. 3 parametrization-tables and weblink Ref. [45
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