6,408 research outputs found
Synchrotron radiation by fast fermions in heavy-ion collisions
We study the synchrotron radiation of gluons by fast quarks in strong
magnetic field produced by colliding relativistic heavy-ions. We argue that due
to high electric conductivity of plasma, time variation of the magnetic field
is slow and estimate its relaxation time. We calculate the energy loss due to
synchrotron radiation of gluons by fast quarks. We find that the typical energy
loss per unit length for a light quark at LHC is a few GeV per fm. This effect
alone predicts quenching of jets with up to about 20 GeV. We also show
that the spin-flip transition effect accompanying the synchrotron radiation
leads to a strong polarization of quarks and leptons with respect to the
direction of the magnetic field. Observation of the lepton polarization may
provide a direct evidence of existence of strong magnetic field in heavy-ion
collisions.Comment: 10 pages, 6 figures; v3: estimate of the relaxation time of magnetic
field is revised, acknowledgment adde
Pseudo-epsilon expansion and the two-dimensional Ising model
Starting from the five-loop renormalization-group expansions for the
two-dimensional Euclidean scalar \phi^4 field theory (field-theoretical version
of two-dimensional Ising model), pseudo-\epsilon expansions for the Wilson
fixed point coordinate g*, critical exponents, and the sextic effective
coupling constant g_6 are obtained. Pseudo-\epsilon expansions for g*, inverse
susceptibility exponent \gamma, and g_6 are found to possess a remarkable
property - higher-order terms in these expansions turn out to be so small that
accurate enough numerical estimates can be obtained using simple Pade
approximants, i. e. without addressing resummation procedures based upon the
Borel transformation.Comment: 4 pages, 4 tables, few misprints avoide
Ballistic Electron Quantum Transport in Presence of a Disordered Background
Effect of a complicated many-body environment is analyzed on the electron
random scattering by a 2D mesoscopic open ballistic structure. A new mechanism
of decoherence is proposed. The temperature of the environment is supposed to
be zero whereas the energy of the incoming particle can be close to or
somewhat above the Fermi surface in the environment. The single-particle
doorway resonance states excited in the structure via external channels are
damped not only because of escape through such channels but also due to the
ulterior population of the long-lived environmental states. Transmission of an
electron with a given incoming through the structure turns out to be
an incoherent sum of the flow formed by the interfering damped doorway
resonances and the retarded flow of the particles re-emitted into the structure
by the environment. Though the number of the particles is conserved in each
individual event of transmission, there exists a probability that some part of
the electron's energy can be absorbed due to environmental many-body effects.
In such a case the electron can disappear from the resonance energy interval
and elude observation at the fixed transmission energy thus resulting
in seeming loss of particles, violation of the time reversal symmetry and, as a
consequence, suppression of the weak localization. The both decoherence and
absorption phenomena are treated within the framework of a unit microscopic
model based on the general theory of the resonance scattering. All the effects
discussed are controlled by the only parameter: the spreading width of the
doorway resonances, that uniquely determines the decoherence rateComment: 7 pages, 1 figure. The published version. A figure has been added;
the list of references has been improved. Some explanatory remarks have been
include
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