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Main Authors: Chang, Wen-Bin, Hou, De-fu
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.04966
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author Chang, Wen-Bin
Hou, De-fu
author_facet Chang, Wen-Bin
Hou, De-fu
contents In this paper, we use a five-dimensional Einstein-dilaton-two-Maxwell holographic QCD model to investigate the dissociation effects of $J/Ψ$ and $Υ(1S)$ states in an anisotropic medium by calculating their spectral functions. First, we present the holographic quarkonium masses at zero temperature via Physics-Informed Neural Networks. Then, at finite temperature, we derive the spectral functions, representing heavy vector mesons as peaks, and observe that with increasing anisotropy, temperature, chemical potential, and warp factor, the peak height diminishes while its width expands, indicating an accelerated dissociation process. Additionally, the results indicate the anisotropy induces a stronger dissociation effect in the direction parallel to the polarization compared to the perpendicular, revealing the anisotropy's directional influence.
format Preprint
id arxiv_https___arxiv_org_abs_2403_04966
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Heavy quarkonium spectral function in an anisotropic background
Chang, Wen-Bin
Hou, De-fu
High Energy Physics - Phenomenology
In this paper, we use a five-dimensional Einstein-dilaton-two-Maxwell holographic QCD model to investigate the dissociation effects of $J/Ψ$ and $Υ(1S)$ states in an anisotropic medium by calculating their spectral functions. First, we present the holographic quarkonium masses at zero temperature via Physics-Informed Neural Networks. Then, at finite temperature, we derive the spectral functions, representing heavy vector mesons as peaks, and observe that with increasing anisotropy, temperature, chemical potential, and warp factor, the peak height diminishes while its width expands, indicating an accelerated dissociation process. Additionally, the results indicate the anisotropy induces a stronger dissociation effect in the direction parallel to the polarization compared to the perpendicular, revealing the anisotropy's directional influence.
title Heavy quarkonium spectral function in an anisotropic background
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2403.04966