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Main Authors: Hanafy, Mahmoud, Tawfik, Abdel Nasser, Maher, Muhammad
Format: Preprint
Published: 2021
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Online Access:https://arxiv.org/abs/2109.03701
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author Hanafy, Mahmoud
Tawfik, Abdel Nasser
Maher, Muhammad
author_facet Hanafy, Mahmoud
Tawfik, Abdel Nasser
Maher, Muhammad
contents We further investigate the applicability of our previously suggested quantum-mechanically correlated statistical hadron gas model (HRG) to the ideal hadron resonance gas model (IHRG), which is inspired by a Beth-Uhlenbeck corrected form of the equation of state (EoS). We compute the ratios of several particle yields, both equal-mass pairs ($\bar{p} / p$, $K^-/ K^+$, $π^-/ π^+$, $\barΛ/ Λ$, $\barΣ/ Σ$, $\barΩ/ Ω$) and unequal-mass pairs ($p/ π^+$, $k^+/ π^+$, $k^-/ π^-$, $Λ/ π^-$, $\bar{p}/ π^-$, $Ω/π^-$) and investigate how these ratios change with the center-of-mass energy. Next, we present a comparative analysis of the outputs of our suggested HRG model and the IHRG model, Cosmic Ray Monte Carlo (CRMC) EPOS $1.99$ simulations, and experimental data from ALICE, SPS, AGS, and RHIC. When compared to the other models taken into consideration, our HRG model typically shows very close agreement with the experimental results. The proton anomaly reported at top RHIC and LHC energies may be addressed by our new HRG model, which notably exhibits a strong alignment with experimental data for $\bar{p}/ π^-$ and $p/ π^+$ ratios. However, both our HRG model and the IHRG model seem to significantly underestimate some experimental data for ratios involving hadron couples with uneven mass and (multi)strange content, such as $Λ/ π^-$ and $Ω/ π^-$. This emphasizes the necessity of additional research to determine whether thermal hadron gas models are appropriate and stresses the significance of any necessary adjustments to improve their correctness.
format Preprint
id arxiv_https___arxiv_org_abs_2109_03701
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Particle Ratios within a statistically corrected hadron resonance gas model and EPOS event-generator at AGS, SPS, RHIC and LHC Energies
Hanafy, Mahmoud
Tawfik, Abdel Nasser
Maher, Muhammad
High Energy Physics - Phenomenology
We further investigate the applicability of our previously suggested quantum-mechanically correlated statistical hadron gas model (HRG) to the ideal hadron resonance gas model (IHRG), which is inspired by a Beth-Uhlenbeck corrected form of the equation of state (EoS). We compute the ratios of several particle yields, both equal-mass pairs ($\bar{p} / p$, $K^-/ K^+$, $π^-/ π^+$, $\barΛ/ Λ$, $\barΣ/ Σ$, $\barΩ/ Ω$) and unequal-mass pairs ($p/ π^+$, $k^+/ π^+$, $k^-/ π^-$, $Λ/ π^-$, $\bar{p}/ π^-$, $Ω/π^-$) and investigate how these ratios change with the center-of-mass energy. Next, we present a comparative analysis of the outputs of our suggested HRG model and the IHRG model, Cosmic Ray Monte Carlo (CRMC) EPOS $1.99$ simulations, and experimental data from ALICE, SPS, AGS, and RHIC. When compared to the other models taken into consideration, our HRG model typically shows very close agreement with the experimental results. The proton anomaly reported at top RHIC and LHC energies may be addressed by our new HRG model, which notably exhibits a strong alignment with experimental data for $\bar{p}/ π^-$ and $p/ π^+$ ratios. However, both our HRG model and the IHRG model seem to significantly underestimate some experimental data for ratios involving hadron couples with uneven mass and (multi)strange content, such as $Λ/ π^-$ and $Ω/ π^-$. This emphasizes the necessity of additional research to determine whether thermal hadron gas models are appropriate and stresses the significance of any necessary adjustments to improve their correctness.
title Particle Ratios within a statistically corrected hadron resonance gas model and EPOS event-generator at AGS, SPS, RHIC and LHC Energies
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2109.03701