Abstract
The in medium dynamics of heavy particles are governed by transport coefficients. The heavy quark momentum diffusion coefficient, $\kappa$, is an object of special interest in the literature, but one which has proven notoriously difficult to estimate, despite the fact that it has been computed by weak-coupling methods at next-to-leading order accuracy, and by lattice simulations of the pure SU(3) gauge theory. Another coefficient, $\gamma$, has been recently identified. It can be understood as the dispersive counterpart of $\kappa$. Little is known about $\gamma$. Both $\kappa$ and $\gamma$ are, however, of foremost importance in heavy quarkonium physics as they entirely determine the in and out of equilibrium dynamics of quarkonium in a medium, if the evolution of the density matrix is Markovian, and the motion, quantum Brownian; the medium could be a strongly or weakly coupled plasma. In this paper, using the relation between $\kappa$, $\gamma$ and the quarkonium in medium width and mass shift respectively, we evaluate the two coefficients from existing 2+1 flavor lattice QCD data. The resulting range for $\kappa$ is consistent with earlier determinations, the one for $\gamma$ is the first non-perturbative determination of this quantity.
Highlights
Heavy quarkonium has long been theorized to serve as a probe of the medium formed in heavy-ion collisions with the purpose to detect a new state of matter, the quark gluon plasma (QGP) [1]
II, we summarize some recent progress in the study of the out of equilibrium dynamics of heavy particles and, in particular, heavy quarkonium in a medium, supplying the relevant background for the results to follow
The Lindblad equation describing the heavy quarkonium evolution in the hot medium created at the early stages of high-energy heavy-ion collisions requires, under some conditions, only two parameters to describe the interaction of the heavy quark-antiquark pair with the medium [2,3,43]
Summary
Heavy quarkonium has long been theorized to serve as a probe of the medium formed in heavy-ion collisions with the purpose to detect a new state of matter, the quark gluon plasma (QGP) [1]. We focus on the out of equilibrium dynamics of heavy quarkonium in the medium. Making use of recent results [2,3], we further elaborate on the out of equilibrium dynamics under the assumptions that the evolution of the quarkonium density is Markovian, and the motion, quantum Brownian. We emphasize the relation that exists, under these conditions, between the quarkonium dynamics and the transport coefficient κ, describing the momentum diffusion of a heavy quark in a medium, and γ, the dispersive counterpart
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