Abstract
We study systematically the topological charge density and the chiral density correlations in the early stage of high energy nuclear collisions: the intial condition is given by the McLerran-Venugopalan model and the evolution of the gluon fields is studied via the Classical Yang-Mills equations up to proper time $\tau\approx 1$ fm/c for an $SU(2)$ evolving Glasma. Topological charge is related to the gauge invariant $\bm E \cdot \bm B$ where $\bm E$ and $\bm B$ denote the color-electric and color-magnetic fields, while the chiral density is produced via the chiral anomaly of Quantum Chromodynamics. We study how the correlation lengths are related to the collision energy, and how the correlated domains grow up with proper time in the transverse plane for a boost invariant longitudinal expansion. We estimate the correlation lengths of both quantities, that after a short transient results of the order of the typical energy scale of the model, namely the inverse of the saturation scale. We estimate the proper time for the formation of a steady state in which the production of the chiral density in the transverse plane per unit rapidity slows down, as well as the amount of chiral density that would be present at the switch time between the Classical Yang-Mills evolution and the relativistic transport or hydro for the quark-gluon plasma phase.
Highlights
The study of the initial condition in high energy collisions is a difficult but interesting problem related to the physics of relativistic heavy ion collisions (RHICs), as well as to that of high energy proton-proton and proton-nucleus collisions
In the saturation region the gluon occupation number is large enough that classical effective field theories (EFTs) can be used [5,6,7,8,9]: the Lorentz-contracted colliding nuclei are idealized to fly along the light cone, with the large-x partons behaving as static sources of the small-x modes that make the color-glass condensate (CGC) fields inside the two nuclei, see Refs. [2,3,4,10,11,12,13] for reviews
We have studied the correlations of the topological charge density, ρT, carried by the strong gluon fields in the early stage of high energy nuclear collisions; besides, we have analyzed the production and the correlations of the chiral density per unit rapidity in the transverse plane, n5, produced by the chiral anomaly of Quantum Chromodynamics (QCD)
Summary
The study of the initial condition in high energy collisions is a difficult but interesting problem related to the physics of relativistic heavy ion collisions (RHICs), as well as to that of high energy proton-proton (pp) and proton-nucleus (pA) collisions. The dynamics of the central rapidity region is determined by the small Bjorken x gluons before the collision where saturation takes place [1,2,3,4]. In the saturation region the gluon occupation number is large enough that classical effective field theories (EFTs) can be used [5,6,7,8,9]: the Lorentz-contracted colliding nuclei are idealized to fly along the light cone, with the large-x partons behaving as static sources of the small-x modes that make the color-glass condensate (CGC) fields inside the two nuclei, see Refs. Color sources form on the two collision sheets as a result of the interaction of the two CGC colliding sheets, in such a way longitudinal color electric, E, and color magnetic, B, fields are formed: this particular field
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