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Main Authors: Kahangirwe, Micheal, Gonzalez, Irene, Muñoz, Jorge A., Ratti, Claudia, Vovchenko, Volodymyr
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.04588
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author Kahangirwe, Micheal
Gonzalez, Irene
Muñoz, Jorge A.
Ratti, Claudia
Vovchenko, Volodymyr
author_facet Kahangirwe, Micheal
Gonzalez, Irene
Muñoz, Jorge A.
Ratti, Claudia
Vovchenko, Volodymyr
contents In this study, we assess the effectiveness and robustness of the recently proposed $T'$-expansion scheme for expanding the equation of state of strongly interacting matter to finite density, by comparing its performance relative to the conventional Taylor expansion method in various effective QCD models. We use baryon number density and its susceptibilities to calculate the expansion coefficients in the $T'$-expansion scheme with and without the Stefan-Boltzmann limit correction. Our methodology involves comparing truncation orders to exact solutions to assess the scheme's accuracy. We utilize Ideal, Excluded Volume, and van der Waals formulations of the Hadron Resonance Gas (HRG) model at low temperatures, and the Cluster Expansion Model at higher temperatures. Our findings indicate that the $T'$-expansion scheme offers superior convergence properties near and above the chiral crossover temperature, where the chiral-criticality-inspired scaling $(\partial/ \partial T)_{μ_B} \sim (\partial^2/\partial μ_B^2)_T$ holds. However, it shows limited improvement in the HRG models, indicating that it may not be the most suitable choice for describing the hadronic phase.
format Preprint
id arxiv_https___arxiv_org_abs_2408_04588
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Convergence properties of $T'$-Expansion Scheme: Hadron Resonance Gas and Cluster Expansion Model
Kahangirwe, Micheal
Gonzalez, Irene
Muñoz, Jorge A.
Ratti, Claudia
Vovchenko, Volodymyr
Nuclear Theory
In this study, we assess the effectiveness and robustness of the recently proposed $T'$-expansion scheme for expanding the equation of state of strongly interacting matter to finite density, by comparing its performance relative to the conventional Taylor expansion method in various effective QCD models. We use baryon number density and its susceptibilities to calculate the expansion coefficients in the $T'$-expansion scheme with and without the Stefan-Boltzmann limit correction. Our methodology involves comparing truncation orders to exact solutions to assess the scheme's accuracy. We utilize Ideal, Excluded Volume, and van der Waals formulations of the Hadron Resonance Gas (HRG) model at low temperatures, and the Cluster Expansion Model at higher temperatures. Our findings indicate that the $T'$-expansion scheme offers superior convergence properties near and above the chiral crossover temperature, where the chiral-criticality-inspired scaling $(\partial/ \partial T)_{μ_B} \sim (\partial^2/\partial μ_B^2)_T$ holds. However, it shows limited improvement in the HRG models, indicating that it may not be the most suitable choice for describing the hadronic phase.
title Convergence properties of $T'$-Expansion Scheme: Hadron Resonance Gas and Cluster Expansion Model
topic Nuclear Theory
url https://arxiv.org/abs/2408.04588