Abstract
We outline a novel chiral kinetic theory framework for systematic computations of the Chiral Magnetic Effect (CME) in ultrarelativistic heavy-ion collisions. The real part of the fermion determinant in the QCD effective action is expressed as a supersymmetric world-line action of spinning, colored, Grassmanian point particles in background gauge fields, with equations of motion that are covariant generalizations of the Bargmann-Michel-Telegdi and Wong equations. Berry's phase is obtained in a consistent non-relativistic adiabatic limit. The chiral anomaly, in contrast, arises from the phase of the fermion determinant; its topological properties are therefore distinct from those of the Berry phase. We show that the imaginary contribution to the fermion determinant too can be expressed as a point particle world-line path integral and derive the corresponding anomalous axial vector current. Our results can be used to derive a covariant relativistic chiral kinetic theory including the effects of topological fluctuations that has overlap with classical-statistical simulations of the CME at early times and anomalous hydrodynamics at late times.
Highlights
The possibility that topological sphaleron transitions can be identified in heavy-ion collision experiments has aroused great interest
We outlined a worldline framework that can be used for systematic computations of the chiral magnetic effect (CME) in ultrarelativistic heavy-ion collisions
We first expressed the real part of the fermion determinant in the QCD effective action as a supersymmetric worldline action of spinning, colored, Grassmanian point particles in background gauge fields, with equations of motion that are covariant generalizations of the Bargmann-Michel-Telegdi and Wong equations
Summary
The possibility that topological sphaleron transitions can be identified in heavy-ion collision experiments has aroused great interest. A striking manifestation of the role of topology is the chiral magnetic effect (CME) where, as a consequence of the chiral anomaly, an induced current is generated in the direction of the external magnetic field [3,4]. We further outline key elements in the worldline formalism necessary for a first principles derivation of a relativistically covariant kinetic theory One such element is provided by the Euler-Lagrange equations of motion derived from the worldline action for the spinning and colored (in the QCD case) Grassmanian fields [47,48,49,50,51,52,53,54,55,56]. A self-consistent derivation of the detailed structure of the many-body kinetic theory for spinning particles, and of the topological fluctuations induced by the QCD axial anomaly, is out of the scope of this work and will be reported on in the near future [60]
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