Pre-equilibrium photons from the early stages of heavy-ion collisions

Abstract:

We use QCD kinetic theory to compute photon production in the chemically equilibrating Quark-Gluon Plasma created in the early stages of high-energy heavy-ion collisions. We do a detailed comparison of pre-equilibrium photon rates to the thermal photon production. We show that the photon spectrum radiated from a hydrodynamic attractor evolution satisfies a simple scaling form in terms of the specific shear viscosity η/s and entropy density dS/dζ ∼ (Tτ^1/3)^3/2_∞. We confirm the analytical predictions with numerical kinetic theory simulations. We use the extracted scaling function to compute the pre-equilibrium photon contribution in $\sqrt{s_{N N}}$ $\sqrt{s_{N N}}$ = 2.76 TeV 0–20% PbPb collisions. We demonstrate that our matching procedure allows for a smooth switching from pre-equilibrium kinetic to thermal hydrodynamic photon production. Finally, our publicly available implementation can be straightforwardly added to existing heavy ion models.

O. Garcia-Montero, A. Mazeliauskas, P. Plaschke, S. Schlichting, „Pre-equilibrium photons
from the early stages of heavy-ion collisions“, JHEP 2024, 053 (2024).

https://link.springer.com/article/10.1007/JHEP03(2024)053

Related to Project A01