214 research outputs found
The pressure of deconfined QCD for all temperatures and quark chemical potentials
We present a new method for the evaluation of the perturbative expansion of
the QCD pressure which is valid at all values of the temperature and quark
chemical potentials in the deconfined phase and which we work out up to and
including order g^4 accuracy. Our calculation is manifestly four-dimensional
and purely diagrammatic -- and thus independent of any effective theory
descriptions of high temperature or high density QCD. In various limits, we
recover the known results of dimensional reduction and the HDL and HTL
resummation schemes, as well as the equation of state of zero-temperature quark
matter, thereby verifying their respective validity. To demonstrate the overlap
of the various regimes, we furthermore show how the predictions of dimensional
reduction and HDL resummed perturbation theory agree in the regime
T~\sqrt{g}*mu. At parametrically smaller temperatures T~g*mu, we find that the
dimensional reduction result agrees well with those of the nonstatic
resummations down to the remarkably low value T~0.2 m_D, where m_D is the Debye
mass at T=0. Beyond this, we see that only the latter methods connect smoothly
to the T=0 result of Freedman and McLerran, to which the leading small-T
corrections are given by the so-called non-Fermi-liquid terms, first obtained
through HDL resummations. Finally, we outline the extension of our method to
the next order, where it would include terms for the low-temperature entropy
and specific heats that are unknown at present.Comment: 45 pages, 21 figures; v2: minor corrections and clarifications,
references added; v3: Fig 16 added, version accepted for publication in PR
How Much do Heavy Quarks Thermalize in a Heavy Ion Collision?
We investigate the thermalization of charm quarks in high energy heavy ion
collisions. To this end, we calculate the diffusion coefficient in the
perturbative Quark Gluon Plasma and relate it to collisional energy loss and
momentum broadening. We then use these transport properties to formulate a
Langevin model for the evolution of the heavy quark spectrum in the hot medium.
The model is strictly valid in the non-relativistic limit and for all
velocities \gamma v < \alphas^{-1/2} to leading logarithm in . The
corresponding Fokker-Planck equation can be solved analytically for a Bjorken
expansion and the solution gives a simple estimate for the medium modifications
of the heavy quark spectrum as a function of the diffusion coefficient. Finally
we solve the Langevin equations numerically in a hydrodynamic simulation of the
heavy ion reaction. The results of this simulation are the medium modifications
of the charm spectrum and the expected elliptic flow as a
function of the diffusion coefficient.Comment: 34 pages, 9 figures. Inculdes a detailed comparison with Boltzmann
simulation
Fermi spectra and their gauge invariance in hot and dense Abelian and non-Abelian theories
The one-loop Fermi spectra (one-particle and collective ones) are found for
all momenta in the -approximation and their gauge invariance in hot and
dense Abelian and non-Abelian theories is studied. It is shown that the
one-particle spectrum, if the calculation accuracy is kept strictly, is gauge
invariant for all momenta and has two branches as the bare one. The collective
spectrum always has four branches which are gauge dependent including also
their |\q|=0 limit. The exception is the case for which this
spectrum is gauge invariant for all momenta as well.Comment: 16 pages, latex, no figure
SELF-ENERGY PECULIARITIES OF THE HOT GAUGE THEORY AFTER SYMMETRY BREAKING
A tensor representation of the gluon propagator is found within covariant
gauges for a non-Abelian theory after symmetry breaking due to and
the exact equations which determine the dispersion laws of plasma excitations
are explicitly obtained. In the high temperature region and fixing the Feynman
gauge we solved these equations and found the damping of the plasma
oscillations and the shifting of their frequency. The phase transition of a
gauge symmetry restoration is estimated to be .Comment: 13 pages, LaTex, No figure
Infrared Properties of the Hot Gauge Theory after Symmetry Breaking
It is shown that the fictitious infrared pole is eliminated from the hot
gauge theory which acquires a new vacuum after the global gauge symmetry
spontaneously breaking. The nonzero W-condensate is generated and leads to the
screening of the chromomagnetic forces through the scenario with the standard
magnetic mass.Comment: 12 pages, LaTeX, Yukawa Institute Preprint YITP/K-1071 (April 1994
Fermi Excitations in Hot and Dense Quark-Gluon Plasma
The Fermi excitations in hot and dense quark-gluon plasma are studied in the
Feynman gauge using the temperature Green function technique. We find the four
well-separated branches for the case and establish the additional
splitting between them (the four different masses) when . The long
wavelength limit of these excitations is found in the general case of the
massive fermions at finite temperature and densities to give the exact one-loop
spectrum. Simultaneously the many known results are reproduces as its different
limits.Comment: 14 pages, latex, no figure
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