CHARGE–VOLTAGE RELATIONS IN QUANTUM DOT ARRAY FIELD-EFFECT TRANSISTORS

Yurii Sibirnovskii; Khayratdin Kamalov; Abdumukhamed Khudaybergenov

CHARGE–VOLTAGE RELATIONS IN QUANTUM DOT ARRAY FIELD-EFFECT TRANSISTORS

Authors

Yurii Sibirnovskii National Research Nuclear University MEPhI Department of Condensed Matter Physics, Moscow, Russia
Khayratdin Kamalov Karakalpak State University, Department of Physics
Abdumukhamed Khudaybergenov Karakalpak State University, Department of Physics

Abstract

This paper presents a numerical modeling approach to analyze the characteristics of a field-effect transistor (FET) with a quantum dot array channel. The study primarily considers the quantum size distribution, gamma distribution as a function of density, and the resulting energy distributions. Newton’s method is employed to solve the system of nonlinear equations governing quantum transport phenomena. The Laplace equation is used to describe the electrostatic potential, and simulations are conducted in MATLAB and R. The results provide insight into the transistor’s behavior under varying conditions, highlighting the influence of size-dependent energy levels and quantum confinement effects

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Published

2025-06-13

Issue

Vol. 37 (2025)

Section

Articles

License

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

How to Cite

CHARGE–VOLTAGE RELATIONS IN QUANTUM DOT ARRAY FIELD-EFFECT TRANSISTORS. (2025). American Journal of Technology and Applied Sciences, 37, 10-17. https://americanjournal.org/index.php/ajtas/article/view/2988