Heavy quark energy loss far from equilibrium in a strongly coupled collision

TL;DR

This study investigates heavy quark energy loss in a strongly coupled, far-from-equilibrium medium using holography, revealing that equilibrium-based models are often qualitatively accurate but have notable limitations at high rapidity and early times.

Contribution

It demonstrates that equilibrium expressions can describe heavy quark energy loss in far-from-equilibrium conditions, with insights into the effects of rapidity and velocity gradients on the drag force.

Findings

Equilibrium models approximate energy loss after plasma formation.

Time delay observed before significant energy loss begins.

High rapidity causes qualitative changes in drag force direction.

Abstract

We compute and study the drag force acting on a heavy quark propagating through the matter produced in the collision of two sheets of energy in a strongly coupled gauge theory that can be analyzed holographically. Although this matter is initially far from equilibrium, we find that the equilibrium expression for heavy quark energy loss in a homogeneous strongly coupled plasma with the same instantaneous energy density or pressure as that at the location of the quark describes many qualitative features of our results. One interesting exception is that there is a time delay after the initial collision before the heavy quark energy loss becomes significant. At later times, once a liquid plasma described by viscous hydrodynamics has formed, expressions based upon assuming instantaneous homogeneity and equilibrium provide a semi-quantitative description of our results - as long as the rapidity of the heavy quark is not too large. For a heavy quark with large rapidity, the gradients in the velocity of the hydrodynamic fluid result in qualitative consequences for the 'drag' force acting on the quark. In certain circumstances, the force required to drag the quark through the plasma can point opposite to the velocity of the quark, meaning that the force that the plasma exerts on a quark moving through it acts in the same direction as its velocity. And, generically, the force includes a component perpendicular to the direction of motion of the quark. Our results support a straightforward approach to modeling the drag on, and energy loss of, heavy quarks with modest rapidity in heavy ion collisions, both before and after the quark-gluon plasma hydrodynamizes, and provide cautionary lessons at higher rapidity.