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Main Authors: Kuzmin, Matvey V., López, Xoán Mayo, Reiten, Jared, Sadofyev, Andrey V.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2309.00683
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author Kuzmin, Matvey V.
López, Xoán Mayo
Reiten, Jared
Sadofyev, Andrey V.
author_facet Kuzmin, Matvey V.
López, Xoán Mayo
Reiten, Jared
Sadofyev, Andrey V.
contents We study the interplay between the flow and hydrodynamic gradients in jet quenching at first order in opacity. We find that the mixed flow-gradient contributions in jet quenching are enhanced by the medium length, and survive in the eikonal limit, dominating over other medium evolution effects. The resulting modification to the jet quenching parameter and energy loss rate can be substantial, leading to ample phenomenological implications. We also compute the leading corrections to the jet broadening due to the flow velocity gradients, and consider the leading gradient effects in the medium-induced branching for general kinematics, extending the recent considerations of jets in inhomogeneous media. These results can be straightforwardly coupled to matter simulations, providing new opportunities for jet tomography in heavy-ion collisions.
format Preprint
id arxiv_https___arxiv_org_abs_2309_00683
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Jet quenching in anisotropic flowing matter
Kuzmin, Matvey V.
López, Xoán Mayo
Reiten, Jared
Sadofyev, Andrey V.
High Energy Physics - Phenomenology
Nuclear Theory
We study the interplay between the flow and hydrodynamic gradients in jet quenching at first order in opacity. We find that the mixed flow-gradient contributions in jet quenching are enhanced by the medium length, and survive in the eikonal limit, dominating over other medium evolution effects. The resulting modification to the jet quenching parameter and energy loss rate can be substantial, leading to ample phenomenological implications. We also compute the leading corrections to the jet broadening due to the flow velocity gradients, and consider the leading gradient effects in the medium-induced branching for general kinematics, extending the recent considerations of jets in inhomogeneous media. These results can be straightforwardly coupled to matter simulations, providing new opportunities for jet tomography in heavy-ion collisions.
title Jet quenching in anisotropic flowing matter
topic High Energy Physics - Phenomenology
Nuclear Theory
url https://arxiv.org/abs/2309.00683