The theory of an exciton formed from spatially separated electron and hole (the hole is in the quantum dot volume, and the electron is localized at the outer spherical quantum dot–dielectric matrix interface) is developed within the modified effective mass method. The effect of significantly increasing the exciton binding energy in quantum dots of zinc selenide, synthesized in a borosilicate glass matrix, relative to that in a zinc selenide single crystal is revealed. It was shown that the short-wavelength shift of the peak of the low-temperature luminescence spectrum of samples containing zinc-selenide quantum dots, observed under the experimental conditions, is caused by quantum confinement of the ground-state energy of the exciton with a spatially separated electron and hole. A review devoted to the theory of excitonic quasimolecules (biexcitons) (formed of spatially separated electrons and holes) in a nanosystem that consists of ZnSe quantum dots synthesized in a borosilicate glass matrix is developed within the context of the modified effective mass approximation. It is shown that biexciton (exciton quasimolecule) formation is of the threshold character and possible in nanosystem, in with the spacing between the quantum dots surfaces is larger than a certain critical spacing. On the basis of analogy spectroscopy of electronic states of superatoms (or artificial atoms) and individual alkali metal atoms theoretically predicted a new artificial atom, which is similar to the new alkali metal atom.
| Published in |
Optics (Volume 3, Issue 6-1)
This article belongs to the Special Issue Optics and Spectroscopy of the Charge Carriers and Excitons States in Quasi - Zero - Dimensional Nanostructures |
| DOI | 10.11648/j.optics.s.2014030601.13 |
| Page(s) | 10-21 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Excitons, Modified Effective Mass Method, Exciton Binding Energy, Quantum Dots, Excitonic Quasimolecules, Biexcitons, Spatially Separated Electrons and Holes, Superatoms
| [1] | Ekimov, A., Onushchenko, A., (1981). Zize quantization of electrons in microcrystals. Journal Experimental Theoretical Physics Letters. 34, 345-348. |
| [2] | Ekimov, A., Onushchenko, A., (1984). Zize quantization of electrons in semiconductor microcrystals. Journal Experimental Theoretical Physics Letters. 40, 1136-1139. |
| [3] | Ekimov, A., Efros, A., (1985). Excitons in semiconductor microcrystals. Solid State Communication. 56, 921-924. |
| [4] | Ekimov, A., Onushchenko, A., Efros, A., (1986). Zize quantization of electron-hole pairs in nanocrystals. Journal Experimental Theoretical Physics Letters. 43, 376-379. |
| [5] | Chepik, D., Efros, A., Ekimov, A., (1990). Spectroscopy of excitons in semiconductor nanocrystals. Journal of Luminescence. 47, 113-118. |
| [6] | Ekimov, A., Hache, F., Schanne-Klein, M., (2003). Optical properties semiconductor quantum dots. Journal Optical Society American. B 20, 100 -108. |
| [7] | Grabovskis, V., Dzenis, Y., Ekimov, A., (1989). Fotoluminescences of excitons in semiconductor nanocrystals. Physics Solid State. 31, 149 -152. |
| [8] | Alferov, J.I., (2002). Progress development in semiconductor nanostructures. Physics Uspekhi. 172, 1068 - 1074. |
| [9] | Alferov, J.I., (1998). Optical properties in semiconductor nanostructures. Semiconductors. 32, 1-8. |
| [10] | Bondar, V.N., Brodin, M.S., (2010). Optical properties semiconoductor quantum dots. Semiconductors. 44, 884-890. |
| [11] | Efros, A.L., Efros, Al.L., Interband absorption light in semiconductor sphere. (1982). Sov. Phys. Semiconductors. 16, 955- 962. |
| [12] | Pokutnyi, S.I., (2004). Size quantization Stark effect in semiconductor quantum dots. J. Appl. Phys. 96, 1115-1122. |
| [13] | Pokutnyi, S.I., (2005). Optical nanolaser heavy hole transitions in quasi – zero – dimensional semiconductors nanosystems. Physics Lett. A. 342, 347-352. |
| [14] | Pokutnyi, S.I., (2007). Exciton states in semiconductor quantum dots in the framework of the modified effective mass method. Semiconductors. 41, 1323-1331. |
| [15] | Pokutnyi, S.I., (2010). Exciton states in semiconductor quantum dots. Semiconductors. 44, 488-493. |
| [16] | Pokutnyi, S.I., (2012). Exciton states in semiconductor nanosystems. Semiconductors. 46, 174-184. |
| [17] | Soloviev, V., Eeichofer, A., (2001). Approximation of effective mass in nanosystems. Physica Status Solidi B. 224, 285-291. |
| [18] | Yeh, C., Zhang, S., Zunger, A., (2004). The effective mass method in nanosystems. Physical Review B. 62, 14408-14416. |
| [19] | Bondar, N., Brodyn, M., (2010). Spectroscopy of semiconbductor quantum dots. Physics E. 42, 1549-1555. |
| [20] | Pokutnyi, S.I., (2013). Binding energy of the exciton of a spatially separated electron and hole in quasi – zero – dimensional semiconductor nanosystems. Technical Physics Letters. 39, 233-235. |
| [21] | Pokutnyi, S.I., (2013). On an exciton with a spatially separated electron and hole in quasi – zero – dimensional semiconductor nanosystems. Semiconductors. 47, 791 -798. |
| [22] | Pokutnyi, S.I., (2014). Theory of excitons formed from spatially separated electrons and holes in quasi – zero – dimensional semiconductor nanosystems. SOP Transactions Theoretical Physics. 1, 24 -35. |
| [23] | [23] Pokutnyi, S.I., (2013). Biexcitons formed from spatially separated electrons and holes in quasi – zero – dimensional semiconductor nanosystems. Semiconductors. 47, 1626 – 1635. |
| [24] | [24] Pokutnyi, S.I., (2014). Quasi – zero – dimensional nanostructures: Excitonic quasimolecules. J. Appl. Chem. 2, 1- 4. |
| [25] | Efremov, N.A., Pokutny, S.I., (1985). Macroscopic local charge states in ultradispersion media. Sov. Phys. Solid. State. 27, 27- 35. |
| [26] | Efremov, N.A., Pokutny, S.I., (1990). Energy spectrum of exciton in spherical particle. Sov. Phys. Solid. State. 32, 955- 964. |
| [27] | Pokutnyi, S.I., (1992). Size quantization of electron-hole pair in semiconductor quantum dots. Physics Lett. A. 168, 433-438. |
| [28] | Pokutnyi, S.I., (2011). Theory of exciton states in semiconductor nanosystems. Physics Express. 1, 158-164. |
| [29] | Pokutnyi, S.I., Gorbyk, P.P., (2013). Superatoms in quasi – zero – dimensional nanostructures (review). Progr. Phys. Metal. 14, 144 - 168. |
| [30] | Pokutnyi, S.I., Gorbyk, P.P., (2013). Superatoms in quasi – zero – dimensional nanosystems. J. Appl. Chem. 1, 44 - 47. |
| [31] | Pokutnyi, S.I., (2012). Exciton states in quasi – zero – dimensional semiconductor nanosystems: Theory. Phys. Express. 2, 20 - 26. |
| [32] | Pokutnyi, S.I., (2013). Exciton states in quasi – zero – dimensional nanostructures. J. Appl. Chem. 1, 5 - 18. |
| [33] | Lozovik, Y., Nishanov, V., (1976). Exciton Wannier-Mott near the interface. Physics Solid State. 18, 1905-1911. |
| [34] | Keldysh , L., (1979). The interaction of the electrons in a thin films. Journal Experimental Theoretical Physics Letters. 29, 621-624. |
| [35] | Frish, S.E., (1963). Optical spectra of atoms. Nauka, Moscow [in Russian]. |
APA Style
Sergey I. Pokutnyi. (2014). Theory of Excitons and Excitonic Quasimolecules Formed from Spatially Separated Electrons and Holes in Quasi - Zero - Dimensional Nanosystems. Optics, 3(6-1), 10-21. https://doi.org/10.11648/j.optics.s.2014030601.13
ACS Style
Sergey I. Pokutnyi. Theory of Excitons and Excitonic Quasimolecules Formed from Spatially Separated Electrons and Holes in Quasi - Zero - Dimensional Nanosystems. Optics. 2014, 3(6-1), 10-21. doi: 10.11648/j.optics.s.2014030601.13
AMA Style
Sergey I. Pokutnyi. Theory of Excitons and Excitonic Quasimolecules Formed from Spatially Separated Electrons and Holes in Quasi - Zero - Dimensional Nanosystems. Optics. 2014;3(6-1):10-21. doi: 10.11648/j.optics.s.2014030601.13
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Download@article{10.11648/j.optics.s.2014030601.13,
author = {Sergey I. Pokutnyi},
title = {Theory of Excitons and Excitonic Quasimolecules Formed from Spatially Separated Electrons and Holes in Quasi - Zero - Dimensional Nanosystems},
journal = {Optics},
volume = {3},
number = {6-1},
pages = {10-21},
doi = {10.11648/j.optics.s.2014030601.13},
url = {https://doi.org/10.11648/j.optics.s.2014030601.13},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.optics.s.2014030601.13},
abstract = {The theory of an exciton formed from spatially separated electron and hole (the hole is in the quantum dot volume, and the electron is localized at the outer spherical quantum dot–dielectric matrix interface) is developed within the modified effective mass method. The effect of significantly increasing the exciton binding energy in quantum dots of zinc selenide, synthesized in a borosilicate glass matrix, relative to that in a zinc selenide single crystal is revealed. It was shown that the short-wavelength shift of the peak of the low-temperature luminescence spectrum of samples containing zinc-selenide quantum dots, observed under the experimental conditions, is caused by quantum confinement of the ground-state energy of the exciton with a spatially separated electron and hole. A review devoted to the theory of excitonic quasimolecules (biexcitons) (formed of spatially separated electrons and holes) in a nanosystem that consists of ZnSe quantum dots synthesized in a borosilicate glass matrix is developed within the context of the modified effective mass approximation. It is shown that biexciton (exciton quasimolecule) formation is of the threshold character and possible in nanosystem, in with the spacing between the quantum dots surfaces is larger than a certain critical spacing. On the basis of analogy spectroscopy of electronic states of superatoms (or artificial atoms) and individual alkali metal atoms theoretically predicted a new artificial atom, which is similar to the new alkali metal atom.},
year = {2014}
}
TY - JOUR T1 - Theory of Excitons and Excitonic Quasimolecules Formed from Spatially Separated Electrons and Holes in Quasi - Zero - Dimensional Nanosystems AU - Sergey I. Pokutnyi Y1 - 2014/07/31 PY - 2014 N1 - https://doi.org/10.11648/j.optics.s.2014030601.13 DO - 10.11648/j.optics.s.2014030601.13 T2 - Optics JF - Optics JO - Optics SP - 10 EP - 21 PB - Science Publishing Group SN - 2328-7810 UR - https://doi.org/10.11648/j.optics.s.2014030601.13 AB - The theory of an exciton formed from spatially separated electron and hole (the hole is in the quantum dot volume, and the electron is localized at the outer spherical quantum dot–dielectric matrix interface) is developed within the modified effective mass method. The effect of significantly increasing the exciton binding energy in quantum dots of zinc selenide, synthesized in a borosilicate glass matrix, relative to that in a zinc selenide single crystal is revealed. It was shown that the short-wavelength shift of the peak of the low-temperature luminescence spectrum of samples containing zinc-selenide quantum dots, observed under the experimental conditions, is caused by quantum confinement of the ground-state energy of the exciton with a spatially separated electron and hole. A review devoted to the theory of excitonic quasimolecules (biexcitons) (formed of spatially separated electrons and holes) in a nanosystem that consists of ZnSe quantum dots synthesized in a borosilicate glass matrix is developed within the context of the modified effective mass approximation. It is shown that biexciton (exciton quasimolecule) formation is of the threshold character and possible in nanosystem, in with the spacing between the quantum dots surfaces is larger than a certain critical spacing. On the basis of analogy spectroscopy of electronic states of superatoms (or artificial atoms) and individual alkali metal atoms theoretically predicted a new artificial atom, which is similar to the new alkali metal atom. VL - 3 IS - 6-1 ER -
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