Holographic Heavy Quark Energy Loss in the Hybrid Model

TL;DR

This paper develops a unified model for heavy quark energy loss in strongly coupled plasma, combining different regimes to better match experimental data on mesons and jets.

Contribution

It introduces an ansatz that seamlessly integrates ultrarelativistic and non-relativistic energy loss regimes within the Hybrid Model.

Findings

Predictions for D- and B-meson suppression match experimental data.

Model accurately describes azimuthal anisotropies of heavy-flavor particles.

Provides a consistent framework for heavy quark energy loss at all velocities.

Abstract

To date, holographic calculations in strongly coupled plasma have provided separate descriptions for the rates of energy loss either for ultrarelativistic massless quarks and gluons or for infinitely massive quarks, with the latter calculation valid for $\sqrt{\gamma} < M/(\sqrt{\lambda}T)$, where $\gamma$ is the Lorentz boost factor for a heavy quark with velocity $v$ and mass $M$ moving through plasma with 't Hooft coupling $\lambda$ and temperature $T$. These two calculations should apply sequentially in the description of the energy loss of a heavy quark that starts out ultrarelativistic, loses energy, slows down, becomes non-relativistic at later times, and ultimately comes to rest and diffuses in the strongly coupled plasma. We provide an ansatz for uniquely incorporating both regimes to give an approximate but unified description of how a heavy quark that is initially ultrarelativistic loses energy all the way until it comes to rest. We implement this ansatz in the Hybrid Strong/Weak Coupling Model. With this new, consistent, treatment of heavy quark energy loss at strong coupling, we confront our predictions for the suppression and azimuthal anisotropies of D- and B-mesons, as well as B-tagged jets, with available experimental data.