Chiral magnetic and vortical effects in high-energy nuclear collisions—A status report

Kharzeev, Dmitri E.; Liao, Jinfeng; Voloshin, S. A.; Wang, G.

doi:10.1016/j.ppnp.2016.01.001

Cited by 732 publications

(690 citation statements)

References 213 publications

(364 reference statements)

Supporting

Mentioning

676

Contrasting

Order By: Relevance

“…Similarly the unitary matrix needed to thermalize the gluon propagator in the vacuum is given by distribution function, 16) where the distribution function for gluons is given by…”

Section: Gluon Propagatormentioning

confidence: 99%

“…Moreover the magnetic field may be assumed uniform because even though the spatial distribution of the magnetic field is globally inhomogeneous, but in the central region of the overlapping nuclei, the magnetic field in the transverse plane varies very smoothly, which is noticed in the hadron-string simulations [9] for Au-Au collisions at √ s N N = 200 GeV with an impact parameter, b = 10 fm. Therefore, a large number of QCD related phenomena are investigated in the strong and homogeneous magnetic field, such as the chiral magnetic effect related to the generation of electric current parallel to the magnetic field due to the difference in number of right and left-handed quarks [10][11][12], the axial magnetic effect due to the flow of energy by the axial magnetic field [13,14], the chiral vortical effect due to an effective magnetic field in the rotating QGP [15,16], the magnetic catalysis and the inverse magnetic catalysis at finite temperature arising due to the breaking and the restoration of the chiral symmetry [17][18][19][20][21], the thermodynamic properties [22][23][24], the refractive indices and decay constant [25,26] of mesons in a hot magnetized medium, the conformal anomaly and the production of soft photons [27,28] at RHIC and LHC, the dispersion relation in a magnetized thermal QED [29], the synchrotron radiation [30], the dilepton production from both the weakly [31][32][33][34] and the strongly [35] coupled plasma etc.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

One-loop QCD thermodynamics in a strong homogeneous and static magnetic field

Rath

Patra

2017

J. High Energ. Phys.

View full text Add to dashboard Cite

Abstract:We have studied how the equation of state of thermal QCD with two light flavors is modified in a strong magnetic field. We calculate the thermodynamic observables of hot QCD matter up to one-loop, where the magnetic field affects mainly the quark contribution and the gluon part is largely unaffected except for the softening of the screening mass. We have first calculated the pressure of a thermal QCD medium in a strong magnetic field, where the pressure at fixed temperature increases with the magnetic field faster than the increase with the temperature at constant magnetic field. This can be understood from the dominant scale of thermal medium in the strong magnetic field, being the magnetic field, in the same way that the temperature dominates in a thermal medium in the absence of magnetic field. Thus although the presence of a strong magnetic field makes the pressure of hot QCD medium larger, the dependence of pressure on the temperature becomes less steep. Consistent with the above observations, the entropy density is found to decrease with the temperature in the presence of a strong magnetic field which is again consistent with the fact that the strong magnetic field restricts the dynamics of quarks to two dimensions, hence the phase space becomes squeezed resulting in the reduction of number of microstates. Moreover the energy density is seen to decrease and the speed of sound of thermal QCD medium increases in the presence of a strong magnetic field. These findings could have phenomenological implications in heavy ion collisions because the expansion dynamics of the medium produced in non-central ultra-relativistic heavy ion collisions is effectively controlled by both the energy density and the speed of sound.

show abstract

“…Similarly the unitary matrix needed to thermalize the gluon propagator in the vacuum is given by distribution function, 16) where the distribution function for gluons is given by…”

Section: Gluon Propagatormentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

One-loop QCD thermodynamics in a strong homogeneous and static magnetic field

Rath

Patra

2017

J. High Energ. Phys.

View full text Add to dashboard Cite

show abstract

“…In relativistic heavy-ion collisions, this can lead to observable electric charge separation along the direction of the strong magnetic field produced by spectator protons [4][5][6]. This is called the chiral magnetic effect (CME).…”

Section: Introductionmentioning

confidence: 99%

“…The measurements of the charge separation can provide a means to studying the non-trivial QCD topological structures. Extensive theoretical and experimental efforts have been devoted to the search for CME [6] .…”

Section: Introductionmentioning

confidence: 99%

“…This indicates significant background contributions in Pb+Pb collisions at LHC energy. It is predicted that the CME would decrease with the collision energy due to the more rapidly decaying B at higher energies [6]. Hence, the similarity between small-system and heavy-ion collisions at the LHC may be expected, and the situation at RHIC could be different [6].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Chiral magnetic effect search in p+Au, d+Au and Au+Au collisions at RHIC

Zhao

2018

EPJ Web of Conferences

View full text Add to dashboard Cite

Abstract. Metastable domains of fluctuating topological charges can change the chirality of quarks and induce local parity violation in quantum chromodynamics. This can lead to observable charge separation along the direction of the strong magnetic field produced by spectator protons in relativistic heavy-ion collisions, a phenomenon called the chiral magnetic effect (CME). A major background source for CME measurements using the charge-dependent azimuthal correlator (∆γ) is the intrinsic particle correlations (such as resonance decays) coupled with the azimuthal elliptical anisotropy (v 2 ). In heavy-ion collisions, the magnetic field direction and event plane angle are correlated, thus the CME and the v 2 -induced background are entangled. In this report, we present two studies from STAR to shed further lights on the background issue.(1) The ∆γ should be all background in small system p+Au and d+Au collisions, because the event plane angles are dominated by geometry fluctuations uncorrelated to the magnetic field direction. However, significant ∆γ is observed, comparable to the peripheral Au+Au data, suggesting a background dominance in the latter, and likely also in the mid-central Au+Au collisions where the multiplicity and v 2 scaled correlator is similar. (2) A new approach is devised to study ∆γ as a function of the particle pair invariant mass (m inv ) to identify the resonance backgrounds and hence to extract the possible CME signal. Signal is consistent with zero within uncertainties at high m inv . Signal at low m inv , extracted from a two-component model assuming smooth mass dependence, is consistent with zero within uncertainties.

show abstract

Effects of P‐Noninvariance, Particles, and Dynamos

Semikoz,

Sokoloff

2023

Geophysical Monograph Series

View full text Add to dashboard Cite

Chiral magnetic and vortical effects in high-energy nuclear collisions—A status report

Cited by 732 publications

References 213 publications

One-loop QCD thermodynamics in a strong homogeneous and static magnetic field

One-loop QCD thermodynamics in a strong homogeneous and static magnetic field

Chiral magnetic effect search in p+Au, d+Au and Au+Au collisions at RHIC

Effects of P‐Noninvariance, Particles, and Dynamos

Contact Info

Product

Resources

About