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Main Authors: Modarresi-Yazdi, Rouzbeh, Shi, Shuzhe, Gale, Charles, Jeon, Sangyong
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.19966
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author Modarresi-Yazdi, Rouzbeh
Shi, Shuzhe
Gale, Charles
Jeon, Sangyong
author_facet Modarresi-Yazdi, Rouzbeh
Shi, Shuzhe
Gale, Charles
Jeon, Sangyong
contents With the use of MARTINI, a model which considers evolving QCD jets against a fluid dynamical background, it is shown that the introduction of formation time to the parton shower after the initial hard scattering is essential for a simultaneous description of charged hadron and jet $R_{AA}$. This inclusion also improves jet shape ratio at small angle and jet fragmentation function ratios of leading charged hadrons. The MARTINI framework is then aimed at a study of the leading order, next-to-leading-order, and non perturbative collision kernels. Sizable differences in the modification of jet substructure observables, i.e., jet shape and fragmentation functions are observed. Such differences are caused by the difference in the radiation rates of relatively soft gluons that survive in the evolution in medium.
format Preprint
id arxiv_https___arxiv_org_abs_2407_19966
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle QCD jets in a hot and dense medium: a study of shower formation time and collision kernels
Modarresi-Yazdi, Rouzbeh
Shi, Shuzhe
Gale, Charles
Jeon, Sangyong
High Energy Physics - Phenomenology
Nuclear Theory
With the use of MARTINI, a model which considers evolving QCD jets against a fluid dynamical background, it is shown that the introduction of formation time to the parton shower after the initial hard scattering is essential for a simultaneous description of charged hadron and jet $R_{AA}$. This inclusion also improves jet shape ratio at small angle and jet fragmentation function ratios of leading charged hadrons. The MARTINI framework is then aimed at a study of the leading order, next-to-leading-order, and non perturbative collision kernels. Sizable differences in the modification of jet substructure observables, i.e., jet shape and fragmentation functions are observed. Such differences are caused by the difference in the radiation rates of relatively soft gluons that survive in the evolution in medium.
title QCD jets in a hot and dense medium: a study of shower formation time and collision kernels
topic High Energy Physics - Phenomenology
Nuclear Theory
url https://arxiv.org/abs/2407.19966