Modified Kolmogorov Wave Turbulence in QCD matched onto "Bottom-up" Thermalization

TL;DR

This paper studies how modified Kolmogorov wave turbulence affects gluon thermalization times in QCD at RHIC and LHC energies, matching theoretical models with phenomenological estimates and extending the bottom-up thermalization picture.

Contribution

It introduces a modified Kolmogorov wave turbulence model in QCD and connects it with the bottom-up thermalization approach to estimate gluon equilibration times at collider energies.

Findings

Gluon thermalization times are estimated for RHIC and LHC energies.

The gluon liberation coefficient is quantified for both energies.

Modified turbulence scenarios yield different thermalization time estimates.

Abstract

We investigate modification of Kolmogorov wave turbulence in QCD calculating gluon spectra as functions of time in the presence of a low energy source which feeds in energy density in the infrared region at a time-dependent rate. Then considering the picture of saturation constraints as has been constructed in the "bottom-up" thermalization approach we revisit that picture for RHIC center-mass energy, $W = 130 {GeV}$, and also extend it to LHC center-mass energy, $W = 5500 {GeV}$, thus for two cases having an opportunity to calculate the equilibration time, $tau_{eq|therm}$, of the gluon system produced in a central heavy ion collision at mid-rapidity region. Thereby, at RHIC and LHC energies we can match the equilibration time, obtained from the late stage gluon spectrum of the modified Kolmogorov wave turbulence, onto that of the "bottom-up" thermalization and other evolutional approaches as well. In addition, from the revised "bottom-up" approach we find the gluon liberation coefficient to be on the average, $c = 0.81 - 1.06$ at RHIC and $c = 0.50 - 0.56$ at LHC. We also present other phenomenological estimates of $tau_{therm}$ which, at QCD realistic couplings, yield $0.45fm - 0.65fm < tau_{therm} < 0.97fm - 2.72fm$ at RHIC and $0.31fm - 0.40fm < tau_{therm} < 0.86fm - 2.04fm$ at LHC, both reflecting the original and modified Kolmogorov wave turbulent scenarios. In the latter case, at certain conditions, taking also into account both very small and realistic couplings we give estimates - $0.65fm < tau_{therm} < 1.29fm$ at RHIC and $0.52fm < tau_{therm} < 1.16fm$ at LHC, as well as at realistic couplings we find $0.53 < tau_{therm} < 0.7fm$ at RHIC and $0.41 < tau_{therm} < 0.65fm$ at LHC.