THERMOELECTRIC ENERGY CONVERSION: PHYSICAL PRINCIPLES AND METHODS FOR HIGH-PERFORMANCE MATERIAL GROWTH
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Abstract
Thermoelectric instrumentation is today one of the most rapidly developing high-tech fields, both in our country and abroad. Fundamental research by scientists has established the theory for the energetic application of thermoelectric phenomena, opening up broad scientific and practical opportunities to use semiconductor thermoelectric converters effectively in various technical fields.
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1.Priyadarshini Balasubramanian, Manjusha Battabyal*, Raghavan Gopalan. Improving the oxidation resistance of thermoelectric Mg2Si leg with silica coating. Materials Letters 312 (2022) 131599. https://doi.org/10.1016/j.matlet.2021.131599
2.Roberta Farris, Maria Barbara Maccioni, Alessio Filippetti, and Vincenzo Fiorentini. Theory of thermoelectricity in Mg3Sb2 with an energy- and temperature-dependent relaxation time. Article in Journal of Physics Condensed Matter·November 2018. DOI: 10.1088/1361-648X/aaf364; https://www.researchgate.net/publication/329157932
3.Md. Mahmudur Rahman, A.K.M. Ashiquzzaman Shawon, Soon‐Chul Ur. Effect of Excessive Antimony on the Thermoelectric and Transport Properties of Mg3Sb2 Synthesized by Controlled Melting, Pulverizing Followed by Vacuum Hot Pressing. Electronic Materials Letters (2021) 17:102– https://doi.org/10.1007/s13391-020-00251-y
4.Jiawei Zhang, Lirong Song and Bo Brummerstedt Iversen. Insights into the design of thermoelectric Mg3Sb2 and its analogs by combining theory and experiment. npj Computational Materials (2019) 5:76; https://doi.org/10.1038/s41524-019-0215-y.
5.Lihong Huang, Tong Liu, Xiaobo Mo, Guocai Yuan, Runyu Wang, Hang Liu, Xiaobo Lei, Qinyong Zhang, Zhifeng Ren. Thermoelectric performance improvement of p-type Mg3Sb2-based materials by Zn and Ag co-doping. Materials Today Physics 21 (2021) 100564; https://doi.org/10.1016/j.mtphys.2021.100564
6.Thermoelectricity: Electronic Skutterudites". J. Applied Solar Energy 2017 No.2, pp. 37-40.
7.B.M. Abdurakhmanov, M.M. Adilov, M.Kh. Ashurov, Kh.B. Ashurov, Sh.K. Kuchkanov, S.E. Maksimov, B.L. Oxengendler. "Thermoelectric characteristics of granular semiconductors with resonant tunneling of charge carriers for the conversion of the thermal component of solar radiation" J. Applied Solar Energy, 2015. No. 4. S.22-27.
8.10. F.L. Omonboev, L.O. Olimov, B.M. Abdurakhmanov. Conductivity and Seebeck coe cient in granular silicon. The American Journal of Engineering and Technology. March 25, 2021. Pages: 28-35. Doi: https://doi.org/10.37547/tajet/Volume03Issue03-05
9.Patent UZ № FAP 01593 "Method of preparation of thermoelectric material". L.O. Olimov, I.I.
10.Anarboev, A.Mamirov, F.L. Omonboev, M.L. Omonboeva (eds) (2021)
11.Patent Uz IAP 0561 Thermoelectric material and its preparation method. 29.06.2018. Bull., No. 6.
12.B.M. Abdurakhmanov, M.M. Adilov, M.Kh. Ashurov, and others.
13.L.O. Olimov, Anarboyev I.I. Some Electrophysical Properties of Polycrystalline Silicon Obtained in a
14.Solar Oven. Silicon 14(8), PP3817 – 3822. 2022. https://doi.org/10.1007/s12633-021-01596-1
15. L.O. Olimov, I.I. Anarboyev. Some electrophysical properties of polycrystalline silicon obtained in a solar oven. International Journal of Physics & Mathematics, 4(1), 39-45. (2021). https://media.neliti.com/media/publications/410793-some-electrophysical-properties-of-polyc-4e03e9d.pdf
16.L.O. Olimov, I.I. Anarboyev. Microcructure of Polycrystal Silicon Heated by Sunlight. RA Journal Of Applied research. V:07 11 November-2021. Page no.-2669-2671. (2021) Available online at www.rajournals.in