85 research outputs found
Probing the Color Structure of the Perfect QCD Fluids via Soft-Hard-Event-by-Event Azimuthal Correlations
We develop a comprehensive dynamical framework, CIBJET, to calculate on an
event-by-event basis the dependence of correlations between soft ( Gev)
and hard ( Gev) azimuthal flow angle harmonics on the color
composition of near-perfect QCD fluids produced in high energy nuclear
collisions at RHIC and LHC. CIBJET combines consistently predictions of
event-by-event VISHNU2+1 viscous hydrodynamic fluid fields with CUJET3.1
predictions of event-by-event jet quenching. We find that recent correlation
data favor a temperature dependent color composition including bleached
chromo-electric components and an emergent chromo-magnetic degrees
of freedom consistent with non-perturbative lattice QCD information in
the confinement/deconfinement temperature range.Comment: 6 pages, 6 figures; Accepted version to appear in Chinese Physics
Anomalous Chiral Transport in Heavy Ion Collisions from Anomalous-Viscous Fluid Dynamics
Chiral anomaly is a fundamental aspect of quantum theories with chiral
fermions. How such microscopic anomaly manifests itself in a macroscopic
many-body system with chiral fermions, is a highly nontrivial question that has
recently attracted significant interest. As it turns out, unusual transport
currents can be induced by chiral anomaly under suitable conditions in such
systems, with the notable example of the Chiral Magnetic Effect (CME) where a
vector current (e.g. electric current) is generated along an external magnetic
field. A lot of efforts have been made to search for CME in heavy ion
collisions, by measuring the charge separation effect induced by the CME
transport. A crucial challenge in such effort, is the quantitative prediction
for the CME signal. In this paper, we develop the Anomalous-Viscous Fluid
Dynamics (AVFD) framework, which implements the anomalous fluid dynamics to
describe the evolution of fermion currents in QGP, on top of the neutral bulk
background described by the VISH2+1 hydrodynamic simulations for heavy ion
collisions. With this new tool, we quantitatively and systematically
investigate the dependence of the CME signal to a series of theoretical inputs
and associated uncertainties. With realistic estimates of initial conditions
and magnetic field lifetime, the predicted CME signal is quantitatively
consistent with measured change separation data in 200GeV Au-Au collisions.
Based on analysis of Au-Au collisions, we further make predictions for the CME
observable to be measured in the planned isobaric (Ru-Ru v.s. Zr-Zr ) collision
experiment, which could provide a most decisive test of the CME in heavy ion
collisions.Comment: 28 pages, 13 figures; published versio
Quantification of Chiral Magnetic Effect from Event-by-Event Anomalous-Viscous Fluid Mechanics
Chiral Magnetic Effect (CME) is the macroscopic manifestation of the
fundamental chiral anomaly in a many-body system of chiral fermions, and
emerges as anomalous transport current in hydrodynamic framework. Experimental
observation of CME is of great interest and significant efforts have been made
to look for its signals in heavy ion collisions. Encouraging evidence of
CME-induced charge separation has been reported from both RHIC and LHC, albeit
with ambiguity due to potential background contributions. Crucial for
addressing such issue, is the need of quantitative predictions for both CME
signal and the non-CME background consistently, with sophisticated modeling
tool. In this contribution we report a recently developed Anomalous Viscous
Fluid Dynamics (AVFD) framework, which simulates the evolution of fermion
currents in QGP on top of the data-validated VISHNU bulk hydro evolution. In
particular, this framework has been extended to event-by-event simulations with
proper implementation of known flow-driven background contributions. We report
quantitative results from such simulations and evaluate the implications for
interpretations of current experimental measurements. Finally we give our
prediction for the CME signal in upcoming isobaric collisions.Comment: 5 pages, 7 figures; plenary talk at CPOD 2017 conference, Stony Brook
University, Stony Brook, NY. arXiv admin note: substantial text overlap with
arXiv:1704.05531; text overlap with arXiv:1611.0458
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