47 research outputs found
On consistency of hydrodynamic approximation for chiral media
We consider chiral liquids, that is liquids consisting of massless fermions
and right-left asymmetric. In such media, one expects existence of
electromagnetic current flowing along an external magnetic field, associated
with the chiral anomaly. The current is predicted to be dissipation-free. We
consider dynamics of chiral liquids, concentrating on the issues of possible
instabilities and infrared sensitivity. Instabilities arise, generally
speaking, already in the limit of vanishing electromagnetic constant,
. In particular, liquids with non-vanishing chiral chemical
potential might decay into right-left asymmetric states containing vortices.Comment: Published versio
Notes on chiral hydrodynamics within effective theory approach
We address the issue of evaluating chiral effects (such as the newly
discovered chiral separation) in hydrodynamic approximation. The main tool we
use is effective theory which defines interaction in terms of chemical
potentials . In the lowest order in we reproduce recent
results based on thermodynamic considerations. In higher orders the results
depend on details of infrared cutoff. Another point of our interest is an
alternative way of the anomaly matching through introduction of effective
scalar fields arising in the hydrodynamic approximation
Chiral Vortical Effect in Superfluid
We consider rotating superfluid pionic liquid, with superfluidity being
induced by isospin chemical potential. The rotation is known to result in a
chiral current flowing along the axis of the rotation. We argue that in case of
superfluidity the chiral current is realized on fermionic zero modes
propagating along vortices. The current evaluated in this way differs by a
factor of two from the standard one. The reason is that the chiral charge is
carried by zero modes which propagate with speed of light, and thus the liquid
cannot be described by a single (local) velocity, like it is assumed in
standard derivations.Comment: 10 pages. To be published in PRD. Minor changes added; typos fixe
Jet Broadening in Flowing Matter -- Resummation
In this work, we obtain the leading corrections to the jet momentum
broadening distribution in a QCD medium arising from the transverse flow of the
matter. We first derive the single-particle propagator of a highly energetic
parton resumming its multiple interactions with the homogeneous flowing matter,
explicitly keeping the leading subeikonal flow terms. Then, we use this
propagator to obtain the jet broadening distribution and its leading moments.
We show that this distribution becomes anisotropic in the presence of
transverse flow, since its odd moments are generally non-zero and proportional
to the transverse velocity of the medium. Finally, we evaluate several odd
moments, which we compare to the corresponding results at first order in
opacity, showing that accounting for multiple in-medium scatterings is
essential to describe some observables in dense nuclear matter.Comment: 28 pages, 2 figure
Emission spectra of terahertz quantum cascade laser
We calculated energy levels, wave functions, and energies of radiative transitions in terahertz
quantum cascade lasers based on GaAs/Al0.15Ga0.85As heterostructures. Current-voltage characteristics
and current dependences of laser radiation intensity were measured, and the maximum
operating temperatures reaching 85 K were determined. Radiation spectra of quantum cascade
lasers were measured for different temperatures, and the effect of intensity “pumping” from lowfrequency
modes to high-frequency modes was found to happen in the case of an increase in the
current and time delay of the signal capture, which is explained by heating of the sample during
a pulse of the current. Application of the lasers for registration of impurity photoconductivity
signals in semiconductor heterostructures was demonstrated