Semiconductor superlattice zone diagram formation

Authors

DOI:

https://doi.org/10.20535/RADAP.2015.62.100-107

Keywords:

semiconductor superlattice, the input impedance, the band diagram, matching conditions

Abstract

Inroduction. In this paper the input impedance characteristics of unlimited and limited superlattices structures were investigated. Superlattices structures are periodic nanoscale multilayer structures in which a periodic potential of the crystal spatially additionally lattice modulated with potential of this structure.
Superlattices’ impedance model. The expressions for input impedance on the left bound of unlimited crystal structure barrier were formed.
Impedance characteristics of unlimited superlattices. The input impedance characteristics of unlimited structures were formed. The band nature of the superlattices’ structures through the dependence of active component of input impedance was shown.
Impedance characteristics of limited superlattices. By the intercomparison of the reflection coefficient of the limited superlattices and active component of the input impedance of unlimited superlattices was analyzed the formation of the unlimited superlattices’ band diagram. As the result of the analysis of the parameters’ of the forbidden zones of limited superlattices and the number of superlattices’ barriers dependence was analyzed the degree of the parameters’ approximation of the limited superlattices’ band diagrams to the parameters of unlimited superlattice’s band diagram. Three points of matching were found. One point was located in the forbidden zone. The matching condition for the second and the third points meets resonance over-barrier passage of electrons through superlattices.
Conclusions. They were found matching conditions of limited superlattices with the environment on their input as well as the features of the formation of the band diagram of superlattices.

Author Biographies

D. V. Khatian, National Technical University of Ukraine, Kyiv Politechnic Institute, Kiev

Khatyan D. V.

M. A. Gindikina, National Technical University of Ukraine, Kyiv Politechnic Institute, Kiev

Gindikina M. A.

E. A. Nelin, National Technical University of Ukraine, Kyiv Politechnic Institute, Kiev

Nelin E. A.

References

Перелік посилань

Bastard G. Heterostructures and Superlattices, Semiconductor. Encyclopedia of Applied Physics / G. Bastard. – N. Y. : Wiley, 2003. – P. 477–493.

Razeghi M. The Wonder of Nanotechnology: Quantum Optoelectronic Devices and Applications / M. Razeghi, L. Esaki, K. von Klitzing, eds. – Bellingham: SPIE Press, 2013. – 1000 p.

Ахмедов Р. С. Імпедансна модель для наноелектронних структур / Р. С. Ахмедов, Е. А. Нелін // Вісник НТУУ «КПІ». Серія Радіотехніка. Радіоапаратобудування. – 2007. – № 34. – С. 102 – 105.

Водолазька М. В. Вхідні імпедансні характеристики двобар’єрних структур / М. В. Водолазька, О. В. Миколайчик, Є. А. Нелін // Вісник НТУУ «КПІ». Серія Радіотехніка. Радіоапаратобудування, 2014. – № 58. – С. 112–120.

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References

Bastard G. (2003) Heterostructures and Superlattices, Semiconductor. Encyclopedia of Applied Physics, pp. 477–493.

Razeghi M., Esaki L. and Klitzing K. von, eds. (2013) The Wonder of Nanotechnology: Quantum Optoelectronic Devices and Applications. Bellingham: SPIE Press, 1000 p.

Akhmedov, R. S., Nelin, E. A. (2007) Impedance model for nanostructures. Visn. NTUU KPI, Ser. Radioteh. radioaparatobuduv., no. 34, pp. 102-105. (in Ukrainian)

Mikolaychik, O. V., Vodolazka, M. V., Nelin, E. A. (2014) Input impedance characteristics of double barrier structures. Visn. NTUU KPI, Ser. Radioteh. radioaparatobuduv., no. 58, pp. 112-120. (in Ukrainian)

Nelin E. A. (2009) Impedance Characteristics of Crystal-like Structures. Tech. Phys., vol. 54, no. 7, pp. 953-957.

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Published

2015-09-30

How to Cite

Хатян, Д. В., Гіндікіна, М. А. and Нелін, Є. А. (2015) “Semiconductor superlattice zone diagram formation”, Visnyk NTUU KPI Seriia - Radiotekhnika Radioaparatobuduvannia, 0(62), pp. 100-107. doi: 10.20535/RADAP.2015.62.100-107.

Issue

No. 62 (2015)

Section

Functional Electronics. Micro- and Nanoelectronic Technology

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