Prediction of Molar Entropy of Gaseous Molecules for a New Pὃschl-Teller Potential Model

IF 2.3 3区化学 Q3 CHEMISTRY, PHYSICAL

International Journal of Quantum Chemistry Pub Date : 2024-11-14 DOI:10.1002/qua.27505

Maryam Hussein Abdulameer, Ali B. M. Ali, Ahmed K. Nemah, Prakash Kanjariya, Asha Rajiv, Mohit Agarwal, Parjinder Kaur, Abdulrahman A. Almehizia

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引用次数: 0

Abstract

The Pὃschl–Teller potential is a molecular potential energy function that has only been reported for bound state. This Pὃschl–Teller potential is a good representation of many molecules and has not been examined for any thermodynamic property irrespective of its fitness for molecular study. In this study, the molar entropy of four molecules (Pbr, BBr, CsCl, and CsO molecules) is calculated via the molar partition function. The predicted results are compared with the experimental data recorded in the National Institute of Standards and Technology (NIST) database. It is noted that the predicted values for the studied molecules perfectly agree with the experimental results with the following average absolute percentage deviation, PBr is 0.0158%, BBr is 0.0053%, CsCl is 0.0020%, and CsO is 0.0052%. The present model reproduces better results for CsCl and CsO molecules compared to the shifted Tietz–Wei potential and improved Tietz-oscillator previously reported whose average absolute percentage deviation are 0.361% and 0.284% for CsCl and 0.272% and 0.228% for CsO, respectively.

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新型 Pὃschl-Teller 电位模型的气态分子摩尔熵预测

Pὃschl-Teller 电位是一种分子势能函数，目前仅有关于结合态的报道。Pὃschl-Teller 电位能很好地代表许多分子，但尚未对其热力学性质进行研究，无论其是否适用于分子研究。本研究通过摩尔分配函数计算了四种分子（Pbr、BBr、CsCl 和 CsO 分子）的摩尔熵。预测结果与美国国家标准与技术研究院（NIST）数据库中记录的实验数据进行了比较。结果表明，所研究分子的预测值与实验结果完全一致，平均绝对百分比偏差如下：PBr 为 0.0158%，BBr 为 0.0053%，CsCl 为 0.0020%，CsO 为 0.0052%。与以前报告的移位铁茨-魏电势和改进的铁茨-振荡器相比，本模型对 CsCl 和 CsO 分子再现了更好的结果，其平均绝对百分比偏差对 CsCl 而言分别为 0.361% 和 0.284%，对 CsO 而言分别为 0.272% 和 0.228%。

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来源期刊

International Journal of Quantum Chemistry 化学-数学跨学科应用

CiteScore

4.70

自引率

4.50%

发文量

185

审稿时长

2 months

期刊介绍： Since its first formulation quantum chemistry has provided the conceptual and terminological framework necessary to understand atoms, molecules and the condensed matter. Over the past decades synergistic advances in the methodological developments, software and hardware have transformed quantum chemistry in a truly interdisciplinary science that has expanded beyond its traditional core of molecular sciences to fields as diverse as chemistry and catalysis, biophysics, nanotechnology and material science.