The Effect of Hadronic Matter on Parton Energy Loss

TL;DR

This paper introduces a simple modification to parton dispersion relations within jet quenching models, enabling more accurate descriptions of jet modification across the quark-gluon plasma and hadronic phases in heavy-ion collisions.

Contribution

A novel multiplicative correction to parton dispersion relations is proposed, extending jet energy loss modeling into the hadronic phase within the JETSCAPE framework.

Findings

Transport coefficients decrease at lower temperatures, matching expected behavior.

The modified model successfully describes jet suppression and anisotropy across various collision conditions.

Extension into the hadronic phase improves the understanding of jet-medium interactions.

Abstract

Modified thermal distributions (dispersion relations) are introduced within both the MATTER and LBT event generators used to describe jet modification in a heavy-ion collision, within the JETSCAPE framework. Hard partons, propagating through dense matter, scatter off the partonic substructure of the medium, leading to stimulated emission, accompanied by recoiling medium partons. We introduce a simple modification, a multiplicative $(1 + a/T)$ correction to the dispersion relation of quarks and gluons (equivalent to an effective fugacity). This leads to calculated transport coefficients (e.g. $\hat{q}/T^3$) showing the expected behavior of depreciating at lower temperatures, including within the hot hadronic gas. This simple modification recovers the light-like dispersion relations at high temperatures, and introduces an excess depreciation factor for parton populations at lower temperatures, allowing partonic energy loss and recoil calculations to be extended into the hadronic phase. This modified distribution, in combination with initial state cold nuclear matter effects (shadowing), is used to simultaneously describe the nuclear modification factor and elliptic anisotropy of jets and leading hadrons, over multiple centralities and collision energies.