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Research PaperNo Access

New bound-state solutions and statistical properties of the IMK-GIQYP and IMSK-IQYP models in 3D-NRNCPS symmetries

Abdelmadjid Maireche

Abdelmadjid Maireche

https://orcid.org/0000-0002-8743-9926

PMC-Laboratory, Physics Department, Sciences Faculty, University of M’sila, P.O. Box 166, Ichebilia 28000 M’sila, Algeria

E-mail Address: abmaireche@gmail.com

E-mail Address: abdelmadjid.maireche@univ-msila.dz

Search for more papers by this author

https://doi.org/10.1142/S0217732324500299Cited by:1 (Source: Crossref)

Abstract

Within the framework of three-dimensional non-relativistic noncommutative quantum phase-space (3D-NRNCPS) symmetries, we study the three-dimensional deformed Schrödinger equation (3D-DSE) using the improved modified Kratzer plus generalized inverse quadratic Yukawa potential (IMK-GIQYP) and the improved modified screened Kratzer plus inversely quadratic Yukawa potential (IMSK-IQYP) models. For this consideration, the well-known generalized Bopp’s shifts method and standard perturbation theory are used to solve the DSE in the 3D-NRNCPS regime. For the homogeneous (H₂, N₂ and I₂) and heterogeneous (CO, CH and NO) diatomic molecules, the new non-relativistic energy equation and eigenfunction for the IMK-GIQYP and the IMSK-IQYP models in the presence of deformation phase-space are obtained to be sensitive to the atomic quantum numbers ( $j, l, s$ and m), the mixed potential depths ( $D_{e}, r_{e}$ and V) and ( $D_{e}, r_{e}, q$ and $V_{1}$ ), the screening parameters ( $δ$ and $φ$ ), and non-commutativity parameters ( $Θ / \bar{Φ}, χ / \bar{χ}$ and $ζ / \bar{ζ}$ ) for the IMK-GIQYP and the IMSK-IQYP, respectively. We investigate the newly obtained bound state eigenvalues of the DSE in 3D-NRNCPS symmetries using the IMK-GIQYP and the IMSK-IQYP, with appropriate adjustments made to the improved modified Kratzer potential, improved modified screened Kratzer potential, improved generalized inverse quadratic Yukawa potential model and improved inversely quadratic Yukawa potential model. Additionally, in 3D-NRNCPS symmetries, the thermal properties of the IMK-GIQYP and the IMSK-IQYP, including their partition function, mean energy, free energy, specific heat and entropy, are thoroughly examined. Significant areas, including atomic and molecular physics, find many uses for this study.

Keywords:

PACS: 03.65.Ge, 03.65.−w, 03.65.Fd, 03.75.Hh, 12.39.Jh

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Vol. 39, No. 09

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History

Received 6 December 2023

Revised 16 February 2024

Accepted 21 February 2024

Published: 5 April 2024

Keywords