English

Computing Jet Transport Coefficients On The Lattice

High Energy Physics - Lattice 2023-07-19 v1 High Energy Physics - Phenomenology Nuclear Experiment Nuclear Theory

Abstract

The leading jet transport coefficients q^\hat{q} or e^2\hat{e}_{2} encode transverse or longitudinal momentum broadening of a hard parton traversing a hot medium. Understanding their temperature dependence is key to appreciating the observed suppression of high-transverse momentum probes at RHIC or LHC collision energies. We present a first continuum extrapolated result of q^\hat{q} computed on pure SU(3) lattices with non-trivial temperature dependence different from the weak-coupling expectation. We discuss our formalism and its challenges and status in view of obtaining e^2\hat{e}_{2} or of unquenching the calculation. We consider a hard quark subject to a single scattering on the plasma. The transport coefficients are factorized in terms of matrix elements given as integrals of non-local gauge-covariant gluon field-strength field-strength correlators. After the analytic continuation to the deep-Euclidean region, the hard scale permits to recast these as a series of local, gauge-invariant operators. The renormalized leading-twist term in this expansion is closely related to static quantities, and is computed on pure SU(3) lattices (Nτ=4, 6, 8,N_{\tau}=4,~6,~8, and 1010) for a wide range of temperatures, ranging from 200MeV < T < 1GeV. Our estimate for the unquenched result in 2+12+1-flavor QCD has very similar features.

Keywords

Cite

@article{arxiv.2307.08834,
  title  = {Computing Jet Transport Coefficients On The Lattice},
  author = {Amit Kumar and Abhijit Majumder and Ismail Soudi and Johannes H. Weber},
  journal= {arXiv preprint arXiv:2307.08834},
  year   = {2023}
}

Comments

6 pages, 1 figure, HardProbes2023, 26-31 March 2023, Aschaffenburg, Germany

R2 v1 2026-06-28T11:32:59.196Z