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Hauptverfasser: Castaño-Yepes, Jorge David, Muñoz, Enrique
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2509.18219
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author Castaño-Yepes, Jorge David
Muñoz, Enrique
author_facet Castaño-Yepes, Jorge David
Muñoz, Enrique
contents We investigate dilepton production in a thermalized quark--gluon plasma subject to global rotation, in the rigid rotating approximation. We consider a generic process involving quark-antiquark annihilation followed by the emission of a highly energetic virtual photon decaying into a dilepton pair. For this process, we compute the dilepton emission rate from the imaginary part of the photon polarization tensor, at finite temperature and vorticity. Our results show that vorticity induces characteristic modifications in the light dilepton channel, namely $e^-e^+$ production, where the emission spectrum exhibits a suppression at low transverse mass together with a mild shift of the production threshold. This behavior originates from the role of vorticity as an effective spin-dependent chemical potential that alters the available phase-space distribution for the emission process. In contrast, the $μ^-μ^+$ channel is {\color{red}more weakly affected by} the rotational background, thus remaining dominated by its intrinsic mass threshold. The resulting channel dependence highlights a potential phenomenological handle for disentangling rotational effects in heavy-ion collisions: while light dilepton spectra encode the imprints of vorticity in the infrared sector, the muon channel provides a comparatively robust baseline.
format Preprint
id arxiv_https___arxiv_org_abs_2509_18219
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Dilepton Production in a Rotating Thermal Medium: The Rigid Rotation Approximation
Castaño-Yepes, Jorge David
Muñoz, Enrique
High Energy Physics - Phenomenology
High Energy Physics - Theory
We investigate dilepton production in a thermalized quark--gluon plasma subject to global rotation, in the rigid rotating approximation. We consider a generic process involving quark-antiquark annihilation followed by the emission of a highly energetic virtual photon decaying into a dilepton pair. For this process, we compute the dilepton emission rate from the imaginary part of the photon polarization tensor, at finite temperature and vorticity. Our results show that vorticity induces characteristic modifications in the light dilepton channel, namely $e^-e^+$ production, where the emission spectrum exhibits a suppression at low transverse mass together with a mild shift of the production threshold. This behavior originates from the role of vorticity as an effective spin-dependent chemical potential that alters the available phase-space distribution for the emission process. In contrast, the $μ^-μ^+$ channel is {\color{red}more weakly affected by} the rotational background, thus remaining dominated by its intrinsic mass threshold. The resulting channel dependence highlights a potential phenomenological handle for disentangling rotational effects in heavy-ion collisions: while light dilepton spectra encode the imprints of vorticity in the infrared sector, the muon channel provides a comparatively robust baseline.
title Dilepton Production in a Rotating Thermal Medium: The Rigid Rotation Approximation
topic High Energy Physics - Phenomenology
High Energy Physics - Theory
url https://arxiv.org/abs/2509.18219