Analysis of Kinetic Properties and Tunnel-Coupled States in Asymmetrical Multilayer Semiconductor Structures

Keywords: multilayer and nano-sized semiconductor structures, Schrödinger matrix equation, Hamiltonian, electrons, Bastard condition.

Abstract

This study investigates the kinetic properties of both symmetrical and asymmetrical multilayer and nano-sized semiconductor structures. We develop a theoretical framework using various models and mathematical methods to solve the Schrödinger matrix equation for a system of electrons, taking into account the Bastard condition, which considers the difference in the effective masses of current carriers in adjacent layers. We analyze tunnel-coupled electronic states in quantum wells separated by a narrow tunnel-transparent potential barrier. Our findings provide insights into the electronic properties of semiconductor structures, which are crucial for applications in micro- or nanoelectronics and other areas of solid-state physics.

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Published
2024-06-01
Cited
How to Cite
Rasulov, R. Y., Rasulov, V. R., Urinova, K. K., Muminov, I. A., & Akhmedov, B. B. (2024). Analysis of Kinetic Properties and Tunnel-Coupled States in Asymmetrical Multilayer Semiconductor Structures. East European Journal of Physics, (2), 270-273. https://doi.org/10.26565/2312-4334-2024-2-27

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