Application of the exact quantization rule to the relativistic solution of the rotational Morse potential with pseudospin symmetry

AbstractAn approximate analytical solution of the radial Schrödinger equation for the generalized Hulthén potential is obtained by applying an improved approximation of the centrifugal term. The bound state energy eigenvalues and the normalized eigenfunctions are given in terms of hypergeometric polynomials. The results for arbitrary quantum numbers n r and l with different values of the screening parameter δ are compared with those obtained by the numerical method, asymptotic iteration, the Nikiforov-Uvarov method, the exact quantization rule, and variational methods. The results obtained by the method proposed in this work are in a good agreement with those obtained by other approximate methods.

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A Theoretical Study on Vibrational Energies of Molecular Hydrogen and Its Isotopes Using a Semi-classical Approximation

Indonesian Journal of Chemistry ◽

10.22146/ijc.63294 ◽

2021 ◽

Vol 21 (3) ◽

pp. 725

Author(s):

Redi Kristian Pingak ◽

Albert Zicko Johannes ◽

Fidelis Nitti ◽

Meksianis Zadrak Ndii

Keyword(s):

Molecular Hydrogen ◽

Morse Potential ◽

Theoretical Study ◽

Potential Functions ◽

Percentage Error ◽

Quantization Rule ◽

Classical Approximation ◽

Vibrational Energies ◽

Rosen Potential ◽

Better Than

This study aims to apply a semi-classical approach using some analytically solvable potential functions to accurately compute the first ten pure vibrational energies of molecular hydrogen (H2) and its isotopes in their ground electronic states. This study also aims at comparing the accuracy of the potential functions within the framework of the semi-classical approximation. The performance of the approximation was investigated as a function of the molecular mass. In this approximation, the nuclei were assumed to move in a classical potential. The Bohr-Sommerfeld quantization rule was then applied to calculate the vibrational energies of the molecules numerically. The results indicated that the first vibrational transition frequencies (v1ß0) of all hydrogen isotopes were consistent with the experimental ones, with a minimum percentage error of 0.02% for ditritium (T2) molecule using the Modified-Rosen-Morse potential. It was also demonstrated that, in general, the Rosen-Morse and the Modified-Rosen-Morse potential functions were better in terms of calculating the vibrational energies of the molecules than Morse potential. Interestingly, the Morse potential was found to be better than the Manning-Rosen potential. Finally, the semi-classical approximation was found to perform better for heavier isotopes for all potentials applied in this study.

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ROTATIONAL-VIBRATIONAL EIGEN SOLUTIONS OF THE D-DIMENSIONAL SCHRÖDINGER EQUATION FOR THE IMPROVED WEI POTENTIAL

FUDMA Journal of Sciences ◽

10.33003/fjs-2020-0402-174 ◽

2020 ◽

Vol 4 (2) ◽

pp. 269-283

Author(s):

Edwin Samson Eyube ◽

Yabwa Dlama ◽

Umar Wadata

Keyword(s):

Schrödinger Equation ◽

Schrodinger Equation ◽

Goodness Of Fit ◽

Bound State ◽

Fit Indices ◽

Quantization Rule ◽

Exact Quantization Rule ◽

Vibrational Energies ◽

Eigen Solutions ◽

Tietz Potential

In this present study, we have employed the techniques of exact quantization rule and ansatz solution method to obtain closed form expressions for the rotational-vibrational eigensolutions of the D-dimensional Schrödinger equation for the improved Wei potential, for cases of h′ ≠ 0 and h′ = 0. By using our derived energy equation and choosing arbitrary values of n and ℓ, we have computed the bound state rotational-vibrational energies of CO, H2 and LiH for various quantum states. The mean absolute percentage deviation (MAPD) and the Lippincott criterion ware used as a goodness-of-fit indices to compare our result with the Rydberg-Klein-Rees (RKR) and improved Tietz potential data in the literature. MAPD of 0.2862%, 0.2896% and 0.0662% relative to the RKR data for CO ware obtained. For the improved Wei and Morse potential, our computed energy eigenvalues for CO, H2 and LiH are in excellent agreement with existing results in the literature

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