PHYSICOCHEMICAL FOUNDATIONS OF THE FORMATION OF SILICON–METAL COMPOSITE THERMOELECTRIC MATERIALS

Authors

  • Mamirov Abduvoxid Muxammadamin ugli Andijan State Technical Institute

Keywords:

Silicon, composite materials, contact formation via metal particle incorporation, nanocomposite, microstructure, thermoelectric properties, electrophysical properties

Abstract

 This study presents a comprehensive investigation of the physicochemical mechanisms and technological features involved in the formation of silicon-based metal composite materials. Alkali metal atoms were introduced into the silicon crystal lattice using a contact method based on the incorporation of metallic particles, and their interaction with the lattice structure was analyzed in detail. In the subsequent stage, thermal treatment processes were carried out to examine the formation mechanisms of composite phases, diffusion behavior, and structural reorganization phenomena.

The obtained results demonstrate that the spatial distribution of metal atoms, microstructural evolution, and morphological changes significantly influence the thermoelectric and electrical conductivity properties of the material. In addition, it was established that the optimization of doping levels and thermal treatment parameters plays a crucial role in controlling the material properties.

The findings of this research provide an important scientific basis for the development of high-performance silicon-based thermoelectric composite materials, expanding their functional capabilities and enhancing their potential for practical applications.

References

Olimov, L. O. (2010). Adsorption of alkali metals and their effect on electronic properties of grain boundaries in bulk of polycrystalline silicon. Semiconductors, 44(5), 602-604.

Olimov, L. O. (2012). Effect of alkali metals on the electronic properties of grain boundaries on a polycrystalline silicon surface. Semiconductors, 46(7), 898-900.

L.O. Olimov, Applied Solar Energy 44(2), 142–143 (2008) 14. A.G. Korotkih, Thermal conductivity of materials: textbook / Tomsk Polytechnic University (Tomsk: Publishing House of Tomsk Polytechnic University, 2011).

Patent UZ № FAP 01593 "Method of preparation of thermoelectric material". L.O. Olimov, I.I. Anarboev, A.Mamirov, F.L. Omonboev, M.L. Omonboeva (eds) (2021)

L.O. Olimov, U.A. Akhmadaliev, Obtaining granular semiconductor intermetallic compound Zn-Sb and some of its electrical properties. Journal E3S Web of Conferences. September (2023)

Olimov L., Khojimatov I. Thermoelectric properties of silicon oxide //E3S Web of Conferences. – EDP Sciences, 2023. – Т. 458. – С. 01022.

Mamirov, A. M. (2021). Anvar o ‘g ‘li KS THERMOLECTRIC, RESISTANCE, PHOTO ELECTRIC DETECTORS AND ANALYSIS OF SPECTRAL CHARACTERISTICS OF MATERIALS IN THEM. Web of Scientist: International Scientific Research Journal, 2(12), 172-180.

Mamirov, A. M. (2022). Anvar o ‘g ‘li KS Production of micro-and nanoscale silicon granules using powder technology. Texas Journal of Multidisciplinary Studies, 5, 175-179

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Published

2026-04-11

How to Cite

Mamirov Abduvoxid Muxammadamin ugli. (2026). PHYSICOCHEMICAL FOUNDATIONS OF THE FORMATION OF SILICON–METAL COMPOSITE THERMOELECTRIC MATERIALS. Ethiopian International Journal of Multidisciplinary Research, 13(4), 858–862. Retrieved from https://www.eijmr.org/index.php/eijmr/article/view/6071

Issue

Vol. 13 No. 4 (2026): Ethiopian International Journal of Multidisciplinary Research

Section

Articles