Analisis Persamaan Energi Menggunakan Metode Parametrik Nikiforov-Uvarov Untuk Atom Berelektron Tunggal Dengan potensial Hulthen

Penulis

  • Nani Sunarmi UIN Sayyid Ali Rahmatullah Tulungagung

DOI:

https://doi.org/10.52188/jpfs.v5i2.275

Kata Kunci:

Persamaan Energi, Potensial Hulthen, Metode Parametrik Nikiforov-Uvarov

Abstrak

Solusi persamaan Schrodinger dari sistem partikel dapat memberikan infomasi karakteristik dari partikel tersebut. Solusi persamaan Schrodinger dapat memberikan persamaan gelombang dan persamaan energi dari partikel. Persamaan energi partikel diperoleh berdasarkan persamaan Schrodinger bagian radial. Penyelesaian persamaan Schrodinger yang melibatkan potensial khusus dilakukan dengan menggunakan metode aproksimasi. Salah satu potensial khusus dalam sistem atomik yang cukup penting adalah potensial Hulthen. Potensial Hulthen banyak dikaji dalam sistem molekuler serta pada kasus plasma pada atom hidrogen. Penyelesaian persamaan  Schrodinger  untuk atom berelektron tunggal dengan potensial Hulthen dapat diselesaikan dengan metode Parametrik Nikiforov-Uvarov. Metode Parametrik Nikiforov-Uvarov dipilih karena bentuk dari persamaan  Schrodinger   dari sistem dapat direduksi menjadi bentuk umum persamaan diferensial orde dua tipe hipergeometri.  Penyelesaian persamaan energi sistem dilakukan dengan memisahkan bagian radial dari persamaan Schrodinger. Persamaan Schrodinger bagian radial yang telah dipisahkan mengandung suku potensial Hulthen dan suku persamaan energi. Persamaan Schrodinger bagian radial  dirubah menjadi  persamaan diferensial orde dua tipe hipergeometri yang mengandung parameter-parameter yang memenuhi Metode Parametrik Nikiforov-Uvarov. Dengan mensubstitusikan persamaan parameter ke dalam persamaan eigen nilai energi diperoleh persamaan energi partikel .  Persamaan tingkat energi   atom berelektron tunggal dengan potensial Hulthen yang telah diperoleh bergantung pada bilangan kuantum utama ,  serta screening parameter

Referensi

Ahmed, S. A. S., & Buragohain, L. (2010). Exact S-wave Solution of Schr odinger Equation for Quantum Bound State Non-Power Law Systems. Bulg. J. Phys, 37, 133–143.

Akpan, I. O., Inyang, E. P., & William, E. S. (2021). Approximate solutions of the Schrödinger equation with Hulthén-Hellmann potentials for a quarkonium system. Revista Mexicana de Fisica, 67(3), 482–490. https://doi.org/10.31349/RevMexFis.67.482

Antia, A. D., Okon, I. B., Akankpo, A. O., & Usanga, J. B. (2020). Non-Relativistic Bound State Solutions of Modified Quadratic Yukawa plus <i>q</i>-Deformed Eckart Potential. Journal of Applied Mathematics and Physics, 08(04), 660–671. https://doi.org/10.4236/jamp.2020.84051

Bahar, M. K., Soylu, A., & Poszwa, A. (2016). The Hulthén Potential Model for Hydrogen Atoms in Debye Plasma. IEEE Transactions on Plasma Science, 44(10), 2297–2306. https://doi.org/10.1109/TPS.2016.2604421

Berkdemir, C. (2012). Theoretical Concepts of Quantum Mechanics. In Theoretical Concepts of Quantum Mechanics. InTech. https://doi.org/10.5772/2075

Fitriani, S. N., & Suparmi. (2017). Solusi Persamaan Dirac Dengan Spin Simetri Untuk Potensial Scarf Ii Hiperbolik Terdeformasi-Q Plus Tensor Tipe Coulomb Dengan Menggunakan Metode Nikiforov Uvarov. Kappa Journal, 1(1), 13. https://doi.org/10.29408/kappa.v1i1.407

Ikhdair, S. M., & Falaye, B. J. (2013). Approximate analytical solutions to relativistic and nonrelativistic Pöschl-Teller potential with its thermodynamic properties. Chemical Physics, 421, 84–95. https://doi.org/10.1016/j.chemphys.2013.05.021

Ita, B. I., Louis, H., & Magu, T. O. (2017). Bound State Solutions of the Klein Gordon Equation with Woods-Saxon Plus Attractive Inversely Quadratic Potential Via Parametric Nikiforov-Uvarov Method. World Scientific News, 74, 280–287.

Nikiforov, A. F., & Uvarov, V. B. (1988). Special Functions of Mathematical Physics: A Unified Introduction with Applications.

Okon, I. B., Antia, A. D., Akankpo, A. O., & Essien, I. E. (2020). Eigen-Solutions to Schrodinger Equation with Trigonometric Inversely Quadratic Plus Coulombic Hyperbolic Potential. Physical Science International Journal, 24(3), 61–75. https://doi.org/10.9734/psij/2020/v24i330183

Okon, I. B., Omugbe, E., Antia, A. D., Onate, C. A., Akpabio, L. E., & Osafile, O. E. (2021). Spin and pseudospin solutions to Dirac equation and its thermodynamic properties using hyperbolic Hulthen plus hyperbolic exponential inversely quadratic potential. Scientific Reports, 11(1), 1–21. https://doi.org/10.1038/s41598-020-77756-x

Omugbe, E. (2020). Non-relativistic Energy Spectrum of the Deng-Fan Oscillator via the WKB Approximation Method. Asian Journal of Physical and Chemical Sciences, 26–36. https://doi.org/10.9734/ajopacs/2020/v8i130107

Onyenegecha, C. P., Njoku, I. J., Omame, A., Okereke, C. J., & Onyeocha, E. (2021). Dirac equation and thermodynamic properties with the Modified Kratzer potential. Heliyon, 7(9), e08023. https://doi.org/10.1016/j.heliyon.2021.e08023

Purohit, K. R., Parmar, R. H., & Rai, A. K. (2021). Energy and momentum eigenspectrum of the Hulthén-screened cosine Kratzer potential using proper quantization rule and SUSYQM method. Journal of Molecular Modeling, 27(12). https://doi.org/10.1007/s00894-021-04965-0

Siregar, R. E. (2018). Fisika Kuantum. Universitas Padjajaran.

Suparmi, A., Permatahati, L. K., Faniandari, S., Iriani, Y., & Marzuki, A. (2021). Study of Bohr Mottelson Hamiltonian with minimal length effect for Woods-Saxon potential and its thermodynamic properties. Heliyon, 7(5), e06861. https://doi.org/10.1016/j.heliyon.2021.e06861

Sutopo. (2005). Pengantar Fisika Kuantum. In Jurusan Fisika FMIPA UM. Jurusan Fisika FMIPA UM.

Diterbitkan

2022-09-30

Cara Mengutip

Sunarmi, N. (2022). Analisis Persamaan Energi Menggunakan Metode Parametrik Nikiforov-Uvarov Untuk Atom Berelektron Tunggal Dengan potensial Hulthen . Jurnal Pendidikan Fisika Dan Sains, 5(2), 68-74. https://doi.org/10.52188/jpfs.v5i2.275

Terbitan

Vol 5 No 2 (2022): September

Bagian

Articles

Hak Cipta (c) 2022 Nani Sunarmi

Creative Commons License

Artikel ini berlisensi Creative Commons Attribution 4.0 International License.

Copyright Transfer Agreement

The Authors submitting a manuscript do so on the understanding that if accepted for publication, copyright of the article shall be assigned to Jurnal Pendidikan Fisika dan Sains (JPFS) and Physics Education Programs of UNU Cirebon as publisher of the journal.

Copyright encompasses exclusive rights to reproduce and deliver the article in all form and media, including reprints, photographs, microfilms and any other similar reproductions, as well as translations. The reproduction of any part of this journal, its storage in databases and its transmission by any form or media, such as electronic, electrostatic and mechanical copies, photocopies, recordings, magnetic media, etc. , will be allowed only with a written permission from Jurnal Pendidikan Fisika dan Sains (JPFS) and UNU Cirebon.
Authors are permitted to disseminate published articles by sharing the link/DOI of the article at the journal. Authors are allowed to use their articles for any legal purposes deemed necessary without written permission from the journal with an acknowledgment of initial publication to this journal.
Jurnal Pendidikan Fisika dan Sains (JPFS) and UNU Cirebon and the Editorial Board make every effort to ensure that no wrong or misleading data, opinions or statements be published in the journal. In any way, the contents of the articles and advertisements published in the Jurnal Pendidikan Fisika dan Sains (JPFS) are sole and exclusive responsibility of their respective authors and advertisers.