Analisis Spektrum Energi dan Fungsi Gelombang Potensial Non-Central Menggunakan Supersimetri Mekanika Kuantum

Antomi Saregar

Abstract


The objectives of this study were: 1) to describe the results of wave and energy function of the Non-central potential system of potential combinations of trigonometric Poschl-Teller plus Rosen Morse, Coloumb and OH 3D potential, and Rosen Morse trigonometric potential plus Pochl-Teller analyzed using Supersymmetry quantum mechanics (SUSY QM); 2) to know the visualization of wave function and energy level at point 1. This study is a literature study conducted from July 2013 to December 2015. Non-central potential of potential combinations of trigonometric Poschl-Teller potency plus Rosen Morse, Coloumb and OH 3D potential and potential Rosen Morse trigonometry plus Pochl-Teller is a potential that has a shape invariance properties. Recent developments, the SUSY method has been successfully used to create complete and precise mathematical analysis of the resolution of some non-central potentials in a closed system. By applying a lowering operator to a basic level wave function, a basic level wave function is obtained, while a top-level wave function is obtained by using a rising operator operated at a ground-level wave function and so on. While the value of energy in a closed system obtained by using the nature of the invariant shape.

 

Tujuan Penelitian ini adalah: 1) mendeskripsikan hasil  fungsi gelombang dan energi dari sistem potensial Non sentral hasil kombinasi potensial Poschl-Teller trigonometri plus potensial Rosen Morse, Coloumb, dan OH 3D, serta potensial Rosen Morse trigonometri plus Pochl-Teller yang dianalisis menggunakan metode Supersymmetry mekanika kuantum (SUSY QM); 2) mengetahui visualisasidari fungsi gelombangdan tingkat energy pada poin 1. Penelitian ini merupakan studi literatur yang dilakukan mulai bulan Juli 2013 s.d. Desember 2015. Potensial non sentral hasil kombinasi potensial Poschl-Teller trigonometri plus potensial Rosen Morse, Coloumb, dan  OH 3D serta potensial Rosen Morse trigonometri plus Pochl-Teller merupakan potensial yang mempunyai sifat shape invariance.Perkembangan terakhir, metode SUSY telah berhasil digunakan untuk membuat analisis matematis  secara lengkap dan tepat penyelesaian beberapa potensial non sentral dalam sistem tertutup. Dengan mengaplikasikan operator penurun pada fungsi gelombang tingkat dasar diperoleh fungsi gelombang tingkat dasar, sedangkan fungsi gelombang tingkat atas satu diperoleh dengan menggunakan operator penaik yang dioperasikan pada fungsi gelombang tingkat dasar dan seterusnya. Sedangkan nilai energinya dalam sistem tertutup diperoleh dengan menggunakan sifat shape invariant.


Keywords


coulomb; metode supersymmetry; OH 3D; poschl-teller trigonometri; potensial non-sentral

Full Text:

PDF

References


Ballentine, L. E. (2014). Quantum mechanics: a modern development. World Scientific Publishing Co Inc.

Cari, C., Suparmi, S., & Saregar, A. (2016). Solution of the Schrödinger Equation for Trigonometric Scarf Plus Poschl-Teller Non-Central Potential Using Supersymmetry Quantum Mechanics. INDONESIAN JOURNAL OF APPLIED PHYSICS, 4(01), 1-13.

Chen, C. Y., & Dong, S. H. (2005). Exactly complete solutions of the Coulomb potential plus a new ring-shaped potential. Physics Letters A, 335(5), 374-382.

Chen, G. (2005). Solution of the Klein–Gordon for exponential scalar and vector potentials. Physics Letters A, 339(3), 300-303.

Combescure, M., Gieres, F., & Kibler, M. (2004). Are N= 1 and N= 2 supersymmetric quantum mechanics equivalent?. Journal of Physics A: Mathematical and General, 37(43), 10385.

Dutt, R., Gangopadhyaya, A., & Sukhatme, U. P. (1997). Noncentral potentials and spherical harmonics using supersymmetry and shape invariance. American Journal of Physics, 65(5), 400-403.

El Kinani, A. H., & Daoud, M. (2001). Coherent states à la Klauder–Perelomov for the Pöschl–Teller potentials. Physics Letters A, 283(5), 291-299.

Goudarzi, H., & Vahidi, V. (2011). Supersymmetric Approach for Eckart Potential Using the NU Method. Adv. Studies Theor. Phys, 5(10), 469-476.

Gönül, B., & Zorba, İ. (2000). Supersymmetric solutions of non-central potentials. Physics Letters A, 269(2), 83-88.

Gönül, B., & Kocak, M. (2005). Systematic search of exactly solvable non-central potentials. Modern Physics Letters A, 20(05), 355-361.

Ikhdair, S. M., & Sever, R. (2007). Polynomial solution of non-central potentials. International Journal of Theoretical Physics, 46(10), 2384-2395.

Aktas, M. (2007). Exact solutions to a new generalized non-central potential in three dimensions. arXiv preprint quant-ph/0701063.

Meyur, S., & Debnath, S. (2009). Solution of the Schrödinger equation with Hulthén plus Manning-Rosen potential. Lat. Am. J. Phys. Educ, 3(2), 300-306.

Meyur, S., & Debnath, S. (2010). Eigen spectra for Woods-Saxon plus Rosen-Morse potential. Lat. Am. J. Phys. Educ. Vol, 4(3), 587.

Mustafa, M., & Kais, S. (2009). A Venn diagram for supersymmetric, exactly solvable, shape invariant, and Infeld-Hull factorizable potentials. arXiv preprint arXiv:0911.4206.

Xian-Quan, H., Guang, L., Zhi-Min, W., Lian-Bin, N., & Yan, M. (2010). Solving Dirac equation with new ring-shaped non-spherical harmonic oscillator potential. Communications in Theoretical Physics, 53(2), 242.

Dutt, R., Khare, A., & Sukhatme, U. P. (1988). Supersymmetry, shape invariance, and exactly solvable potentials. American Journal of Physics, 56(2), 163-168.

Salehi, H. (2011). Determine the eigen function of Schrodinger equation with non-central potential by using NU method. Applied Mathematics, 2(08), 999.

Salehi, H. (2011). Determine the eigen function of Schrodinger equation with non-central potential by using NU method. Applied Mathematics, 2(08), 999.

Sadeghi.J and Pourhassan. B, 2008, Sadeghia, J., & Pourhassan, B. (2008). Exact Solution of The Non-Central Modified Kratzer Potential Plus a Ring-Shaped Like Potential By The Factorization Method. Electronic Journal of Theoretical Physics, 5(17).

Saregar, A., Suparmi, A., Cari, C., & Yuliani, H. (2013). Analysis of Energy Spectra and Wave Function of Trigonometric Poschl-Teller plus Rosen-Morse Non-Central Potential Using Supersymmetric Quantum Mechanics Approach. RESEARCH INVENTY: International Journal Of Engineering And Science, 2(3), 14-26.

Saregar, A. (2015). Solution Of Schrödinger Equation For Poschl-Teller Plus Scarf Non-Central Potential Using Supersymmetry Quantum Mechanics Aproach. Jurnal Ilmiah Pendidikan Fisika Al-Biruni, 4(1), 25-35.

Sohnius, M. F. (1985). Introducing Supersymmetry (Cambridge CB3 9EW. NHC: England.

Suparmi, A., Cari, C., Handhika, J., Yanuarief, C., & Marini, H. (2012). Approximate Solution of Schrodinger Equation for Modified Poschl-Teller plus Trigonometric Rosen-Morse Non-Central Potentials in Terms of Finite Romanovski Polynomials. IOSR Journal of Applied Physics (IOSR-JAP), 2(2), 43-51.

Suparmi, A. (1992). Desertation, Semiclassical SUSY approace in Quantum Mechanics, Department of Physics, Suny at Albany.

Yasuk. F., Berkdemir C., Berkdemir A. (2005). Phys. A: Math. Gen, 38, 6579-6586.




DOI: http://dx.doi.org/10.24042/jipfalbiruni.v4i2.92

Refbacks

  • There are currently no refbacks.


Creative Commons License

Jurnal ilmiah pendidikan fisika Al-Biruni is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.