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1
Source: St. Petersburg Polytechnical University Journal: Physics and Mathematics, Vol 17, Iss 2 (2024)
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2Academic Journal
Authors: A. A. Soldatov, A. I. Soldatov, M. A. Kostina, A. A. Abouellail, А. А. Солдатов, А. И. Солдатов, М. А. Костина, А. А. Абуеллаиль
Source: Devices and Methods of Measurements; Том 15, № 2 (2024); 87-94 ; Приборы и методы измерений; Том 15, № 2 (2024); 87-94 ; 2414-0473 ; 2220-9506 ; 10.21122/2220-9506-2024-15-2
Subject Terms: неразрушающий контроль, differential sensor, electrode, Seebeck coefficient, nondestructive testing, дифференциальный датчик, электрод, коэффициент Зеебека
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Relation: https://pimi.bntu.by/jour/article/view/868/691; Carreon H. Thermoelectric detection of spherical tin inclusions in copper by magnetic sensing. Journal of Applied Physics. 2000;88(11):6495. DOI:10.1063/1.1322591; Carreon H. Thermoelectric Nondestructive Evaluation of Residual Stress in Shot-Peened Metals. Research in Nondestructive Evaluation. 2002;14(2):59−80. DOI:10.1080/09349840209409705; Nagy PB. Non-destructive methods for materials' state awareness monitoring. Insight: Non-Destructive Testing and Condition Monitoring. 2010;52(2):61−71. DOI:10.1784/insi.2010.52.2.61; Li JF. and et all. High-performance nanostructured thermoelectric materials. Npg Asia Mater. 2010;2(4): 152−158. DOI:10.1038/asiamat.2010.138; Kikuchi M. Dental alloy sorting by the thermoelectric method. European Journal of Dentistry. 2010;4(1):66−70.; Dragunov VK, Goncharov AL. New approaches to the rational manufacturing of combined constructions by EBW. IOP Conference Series: Materials Science and Engineering. 2019;681:012010. DOI:10.1088/1757-899X/681/1/012010; Goncharov A. [et al]. Research of thermoelectric effects and their influence on electron beam in the process of welding of dissimilar steels. IOP Conference Series: Materials Science and Engineering. 2020;759(1):012008, DOI:10.1088/1757-899X/759/1/012008; Kharitonov IA, Rodyakina RV, Goncharov AL. Investigation of magnetic properties of various structural classes steels in weak magnetic fields characteristic for generation of thermoelectric currents in electron beam welding. Solid State Phenomena. 2020;299:1201–1207. DOI:10.4028/www.scientific.net/SSP.299.1201; Carreon H, Medina A. Nondestructive characterization of the level of plastic deformation by thermoelectric power measurements in cold-rolled Ti–6Al–4V samples. Nondestructive Testing and Evaluation. 2007;299311. DOI:10.1080/10589750701546960; Carreon H. Detection of fretting damage in aerospace materials by thermoelectric means. Nondestructive Characterization for Composite Materials, Aerospace Engineering, Civil Infrastructure, and Homeland Security. 2013;8694. DOI:10.1117/12.2009448; Lakshminarayan B, Carreon H, Nagy P, Monitoring of the Level of Residual Stress in Surface Treated Specimens by a Noncontacting Thermoelectric Technique. AIP Conference Procciding. 2003;657:1523–1530. DOI:10.1063/1.1570311; Carreon H. Evaluation of Thermoelectric Methods for the Detection of Fretting Damage in 7075‐T6 and Ti‐6A1‐4V Alloys. Characterization of Minerals, Metals, and Materials. 2015;435–442. DOI:10.1007/978-3-319-48191-3_53; Carreon M, Barriuso S, Barrera G, Gonzálezcarrasco JL, Caballero F. Assessment of blasting induced effects on medical 316 LVM stainless steel by contacting and non-contacting thermoelectric power techniques. Surface and Coatings Technology. 2012;2942–2947. DOI:10.1016/J.SURFCOAT.2011.12.026; Goncharov AL. Investigation of the thermal electromotive force of steels and alloys of different structural grades in electron beam welding. Welding International. 2011;25(9):703–709. DOI:10.1080/09507116.2011.566744; Goncharov AL. [et al]. Investigation of thermoEMF temperature dependences for construction materials of various structural classes. IOP Conf. Series: Materials Science and Engineering. 2019;681:012017. DOI:10.1088/1757-899X/681/1/012017; Li JF, Liu WS, Zhao LD, Zhou M. High-performance nanostructured thermoelectric materials. Npg Asia Mater. 2010;2(4):152–158. DOI:10.1038/asiamat.2010.138; Ciylan B, Yılmaz S. Design of a thermoelectric module test system using a novel test method. International Journal of Thermal Sciences. 2007;46(7):717–725. DOI:10.1016/j.ijthermalsci.2006.10.008; Soldatov AI. [et al]. Control system for device «thermotest». 2016 International Siberian Conference on Control and Communications (SIBCON). 2016;1-5. DOI:10.1109/SIBCON.2016.7491869; Soldatov AA, Seleznev AI, Fiks II, Soldatov AI, Kröning KhM. Nondestructive proximate testing of plastic deformations by differential thermal EMF measurements. Russian Journal of Nondestructive Testing. 2012;48(3):184–186. DOI:10.1134/S1061830912030060; Carreon H. Thermoelectric Detection of Fretting Damage in Aerospace Materials. Russian Journal of Nondestructive Testing. 2014;50(11):684−692. DOI:10.1134/S1061830914110102; Soldatov AI, Soldatov AA, Kostina MA, Kozhemyak OA. Experimental studies of thermoelectric characteristics of plastically deformed steels ST3, 08KP and 12H18N10T. Key Engineering Materials. 2016;685:310−314. DOI:10.4028/www.scientific.net/KEM.685.310; Soldatov AI, Soldatov AA, Sorokin PV, Abouellail AA, Obach II, Bortalevich VY, Shinyakov YA, Sukhorukov MP. An experimental setup for studying electric characteristics of thermocouples. SIBCON 2017 − Proceedings. 2017;79985342017. DOI:10.1109/СИБКОН.2017.7998534; Xuan XC. [et al]. A general model for studying effects of interface layers on thermoelectric devices performance. International Journal of Heat and Mass Transfer. 2002;45(26):5159−5170. DOI:10.1016/S0017-9310(02)00217-X; Burkov AT. [et al]. Methods and technique for thermopower and electrical conductivity measurements of thermoelectric materials at high temperatures. Scientific and technical bulletin of information technologies, mechanics and optics. 2015;15(2):173–195. (In Russ.) DOI:10.17586/2226-1494-2015-15-2-173-195; https://pimi.bntu.by/jour/article/view/868
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3Academic Journal
Authors: Samy Mostafa, Ahmed A. M. El-Amir, Fouad Zahran, Adel Ahmed, Mohamed Elwan, Amal Khalifa, Emad Ewais, Сами Мостафа, Ахмед А. М. Эль-Амир, Фуад Захран, Адель Ахмед, Мохамед Эльван, Амаль Халифа, Эмад М. М. Эвайс
Source: NOVYE OGNEUPORY (NEW REFRACTORIES); № 1 (2024); 59-64 ; Новые огнеупоры; № 1 (2024); 59-64 ; 1683-4518 ; 10.17073/1683-4518-2024-1
Subject Terms: керамика из Zn1 ‒ xMgxO, термоэлектрическая добротность керамики, теплопроводность, электросопротивление, коэффициент Зеебека
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Relation: https://newogneup.elpub.ru/jour/article/view/2141/1731; CRC handbook of thermoelectrics; ed. by D. M. Rowe. ― CRC press, 2018.; Mohammed, M. A. A review of thermoelectric ZnO nanostructured ceramics for energy recovery / M. A. Mohammed, I. Sudin, A. M. Noor [et al.] // International Journal of Engineering & Technology. ― 2018. ― Vol. 7, № 2.29. ― Р. 27‒30. https://www.sciencepubco.com/index.php/ijet/article/view/13120.; Duan, B. Regulation of oxygen vacancy and reduction of lattice thermal conductivity in ZnO ceramic by high temperature and high pressure method / B. Duan, Y. Li, J. Li [et al.] // Ceram. Int. ― 2020. ― Vol. 46, № 16. ― Р. 26176‒26181.; Zeng, C. Enhanced thermoelectric performance of SmBaCuFeO5+δ/Ag composite ceramics / С. Zeng, S. Butt, Y. H. Lin [et al.] // J. Am. Ceram. Soc. ― 2016. ― Vol. 99, № 4. ― Р. 1266‒1270.; Combe, E. Microwave sintering of Ge-doped In2O3 thermoelectric ceramics prepared by slip casting process / E. Combe, E. Guilmeau, E. Savary [et al.] // J. Eur. Ceram. Soc. ― 2015. ― Vol. 35, № 1. ― Р. 145‒151.; Li, W. Promoting SnTe as an eco-friendly solution for p-PbTe thermoelectric via band convergence and interstitial defects / W. Li, L. Zheng, B. Ge [et al.] // Adv. Mater. ― 2017. ― Vol. 29, № 17. ― Article 1605887.; Pashkevich, A. V. Structure, electric and thermoelectric properties of binary ZnO-based ceramics doped with Fe and Co / A. V. Pashkevich, A. K. Fedotov, E. N. Poddenezhny [et al.] // J. Alloys Compd. ― 2022. ― Vol. 895. ― Article 162621.; Tsubota, T. Thermoelectric properties of Al-doped ZnO as a promising oxide material for high-temperature thermoelectric conversion / T. Tsubota, M. Ohtaki, K. Eguchi, H. Arai // J. Mater. Chem. ― 1997. ― Vol. 7, № 1. ― Р. 85‒90.; Abdel-Motaleb, I. M. Thermoelectric devices : principles and future trends / I. M. Abdel-Motaleb, S. M. Qadri // arXiv preprint arXiv. ― 2017. ― 1704. 07742. https://doi.org/10.48550/arXiv.1704.07742.; Radingoana, P. M. (2019). Université Paul SabatierToulouse III).; Lei, L. W. Synthesis and low field transport properties in a ZnO-doped La0.67Ca0.33MnO3 composite / L. W. Lei, Z. Y. Fu, J. Y. Zhang, H. Wang // Mater. Sci. Eng., B. ― 2006. ― Vol. 128, № 1‒3. ― Р. 70‒74.; Janotti, A. Fundamentals of zinc oxide as a semiconductor / A. Janotti, C. G. Van de Walle // Rep. Prog. Phys. ― 2009. ― Vol. 72, № 12. ― Article 126501.; Janotti, A. Native point defects in ZnO / A. Janotti, C. G. Van de Walle // Phys. Rev., B. ― 2007. ― Vol. 76, № 16. ― Article 165202.; Olorunyolemi, T. Thermal conductivity of zinc oxide: from green to sintered state / T. Olorunyolemi, A. Birnboim, Y. Carmel [et al.] // J. Am. Ceram. Soc. ― 2002. ― Vol. 85, № 5. ― Р. 1249‒1253.; Liang, X. Thermoelectric transport properties of naturally nanostructured Ga‒ZnO ceramics : effect of point defect and interfaces / X. Liang // J. Eur. Ceram. Soc. ― 2016. ― Vol. 36, № 7. ― Р. 1643‒1650. https://www.sciencedirect.com/science/article/pii/S095522191630067X.; Lu, L. The resistivity of zinc oxide under different annealing configurations and its impact on the leakage characteristics of zinc oxide thin-tilm / L. Lu, M. Wong // IEEE Transactions on Electron Devices. ― 2014. ― Vol. 61, № 4. ― Р. 1077‒1084.; Wagner, C. D. GE Muilenberg in Handbook of Х-ray photoelectron spectroscopy : a reference book of standard data for use in Х-ray photoelectron spectroscopy / C. D. Wagner. ― Physical Electronics Division, PerkinElmer Corp., Eden Prairie, USA, 1979.; Chen, M. X-ray photoelectron spectroscopy and auger electron spectroscopy studies of Al-doped ZnO films / М. Chen, Х. Wang, Y. H. Yu [et al.] // Appl. Surf. Sci. ― 2000. ― Vol. 158, № 1/2. ― P. 134‒140.; Lin, C. C. Enhanced luminescent and electrical properties of hydrogen-plasma ZnO nanorods grown on wafer-scale flexible substrates / C. C. Lin, H. P. Chen, H. C. Liao, S. Y. Chen // Appl. Phys. Lett. ― 2005. ― Vol. 86, № 18. ― Article 183103.; Lu, Y. F. The effects of thermal annealing on ZnO thin films grown by pulsed laser deposition / Y. F. Lu, H. Q. Ni, Z. H. Mai, Z. M. Ren // J. Appl. Phys. ― 2000. ― Vol. 88, № 1. ― Р. 498‒502.; Valtiner, M. Preparation and characterisation of hydroxide stabilised ZnO (0001)–Zn–OH surfaces / M. Valtiner, S. Borodin, G. Grundmeier // Physical Chemistry Chemical Physics. ― 2007. ― Vol. 9, № 19. ― P. 2406‒2412.; Ullah, M. Effects of Al and B co-doping on the thermoelectric properties of ZnO ceramics sintered in an argon atmosphere / M. Ullah, S. Ullah, A. Manan [et al.] // Appl. Phys., A. ― 2022. ― Vol. 128, № 2. ― Р. 1‒7.; Tsubota, T. Transport properties and thermoelectric performance of (Zn1–yMgy)1–xAlxO / T. Tsubota, M. Ohtaki, K. Eguchi, H. Arai // J. Mater. Chem. ― 1998. ― Vol. 8 (2). ― P. 409‒412.; https://newogneup.elpub.ru/jour/article/view/2141
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4Academic Journal
Authors: Даниил Юрьевич Матвеев
Source: Известия Алтайского государственного университета, Iss 4(126), Pp 36-43 (2022)
Subject Terms: висмут, олово, акцепторная примесь, тонкие пленки, удельное сопротивление, магнетосопротивление, коэффициент холла, коэффициент зеебека, Physics, QC1-999, History (General), D1-2009
File Description: electronic resource
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5Conference
Authors: Vlasova, M. A., Maklakova, A. V., Volkova, N. E.
Subject Terms: КИСЛОРОДНАЯ НЕСТЕХИОМЕТРИЯ, КОЭФФИЦИЕНТ ЗЕЕБЕКА, OXYGEN NON-STOICHIOMETRY, КРИСТАЛЛИЧЕСКАЯ СТРУКТУРА, ЭЛЕКТРОПРОВОДНОСТЬ, THERMAL EXPANSION COEFFICIENT, PHYSICO-CHEMICAL PROPERTIES, ФИЗИКО-ХИМИЧЕСКИЕ СВОЙСТВА, КОЭФФИЦИЕНТ ТЕРМИЧЕСКОГО РАСШИРЕНИЯ, CRYSTAL STRUCTURE, ELECTRICAL CONDUCTIVITY, THERMOPOWER
File Description: application/pdf
Access URL: http://elar.urfu.ru/handle/10995/119860
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6
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7
Source: St. Petersburg Polytechnical University Journal: Physics and Mathematics, Vol 16, Iss 2 (2023)
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8Academic Journal
Authors: Водоріз, Ольга Станіславівна, Тавріна, Тетяна Володимирівна, Ніколаєнко, Ганна Олександиівна, Рогачова, Олена Іванівна
Subject Terms: тверді розчини PbSe1−xTex, полікристали, пресування, мікротвердість, коефіцієнт Зеєбека, електропровідність, поріг перколяції, PbSe1−xTex solid solutions, polycrystals, pressing, microhardness, Seebeck coefficient, electrical conductivity, percolation threshold, твёрдые растворы PbSe1−xTex, поликристаллы, прессование, микротвёрдость, коэффициент Зеебека, электропроводность, порог перколяции
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Relation: Механічні та термоелектричні властивості напівпровідникових твердих розчинів PbSe1−xTex (x = 0–0,045) / О. С. Водоріз, Т. В. Тавріна, Г. О. Ніколаєнко, О. І. Рогачова // Металофізика та новітні технології = Metallophysics and Advanced Technologies. – 2020. – Т. 42, № 4. – С. 487-495.; http://repository.kpi.kharkov.ua/handle/KhPI-Press/61904; orcid.org/0000-0002-2951-4887; orcid.org/0000-0002-8536-6612; orcid.org/0000-0001-7584-656X
Availability: http://repository.kpi.kharkov.ua/handle/KhPI-Press/61904
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9Academic Journal
Authors: S. A. Gridnev, Yu. E. Kalinin, V. A. Makagonov, С. А. Гриднев, Ю. Е. Калинин, В. А. Макагонов
Contributors: This work was financially supported by the Ministry of Education and Science of the Russian Federation according Decree of the Government of the Russian Federation, April 9, 2010 № 218 (Agreement № 03.G25.31.0246), Работа выполнена при финансовой поддержке Министерства образования и науки Российской Федерации в рамках постановления Правительства Российской Федерации от 9 апреля 2010 г. № 218 (Договор № 03.G25.31.0246)
Source: Alternative Energy and Ecology (ISJAEE); № 34-36 (2019); 41-72 ; Альтернативная энергетика и экология (ISJAEE); № 34-36 (2019); 41-72 ; 1608-8298
Subject Terms: переход «полуметалл − полупроводник», Seebeck coefficient, nanostructures, density of states, energy filtration, modulation doping, semimetal−semiconductor transition, коэффициент Зеебека, наноструктуры, плотность состояний, энергетическая фильтрация, модуляционное легирование
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10Academic Journal
Subject Terms: PbSe1−xTex solid solutions, electrical conductivity, твёрдые растворы PbSe1−xTex, пресування, Seebeck coefficient, тверді розчини PbSe1−xTex, прессование, полікристали, електропровідність, порог перколяции, percolation threshold, электропроводность, мікротвердість, pressing, microhardness, микротвёрдость, коефіцієнт Зеєбека, polycrystals, поликристаллы, поріг перколяції, коэффициент Зеебека
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11Conference
Authors: Власова, М. А., Маклакова, А. В., Волкова, Н. Е., Vlasova, M. A., Maklakova, A. V., Volkova, N. E.
Subject Terms: КРИСТАЛЛИЧЕСКАЯ СТРУКТУРА, КИСЛОРОДНАЯ НЕСТЕХИОМЕТРИЯ, ФИЗИКО-ХИМИЧЕСКИЕ СВОЙСТВА, ЭЛЕКТРОПРОВОДНОСТЬ, КОЭФФИЦИЕНТ ТЕРМИЧЕСКОГО РАСШИРЕНИЯ, КОЭФФИЦИЕНТ ЗЕЕБЕКА, CRYSTAL STRUCTURE, OXYGEN NON-STOICHIOMETRY, PHYSICO-CHEMICAL PROPERTIES, ELECTRICAL CONDUCTIVITY, THERMAL EXPANSION COEFFICIENT, THERMOPOWER
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Relation: Актуальные проблемы развития естественных наук : сборник статей участников XXV Областного конкурса научно-исследовательских работ «Научный Олимп» по направлению «Естественные науки». — Екатеринбург, 2022; http://elar.urfu.ru/handle/10995/119860
Availability: http://elar.urfu.ru/handle/10995/119860
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12Academic Journal
Contributors: ELAKPI
Source: Information and Telecommunication Sciences; № 2 (2016); 20-27
Subject Terms: теплопровідність, теплопроводность, SiGe, нитевидные кристаллы, whiskers, Seebeck coefficient, 02 engineering and technology, thermoelectric properties, 01 natural sciences, thermal conductivity, термоелектричні властивості, ниткоподібні кристали, 0103 physical sciences, коефіцієнт Зеєбека, термоэлектрические свойства, 0210 nano-technology, коэффициент Зеебека
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Linked Full TextAccess URL: https://ela.kpi.ua/bitstream/123456789/37359/1/ITS2016_7-2_p20-27.pdf
https://www.sciencedirect.com/science/article/abs/pii/S1369800106002095
https://ela.kpi.ua/handle/123456789/37359
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13
Authors: Chernev, Igor, Subbotin, Evgenii, Argunov, Efim, Kozlov, Aleksei, Gerasimenko, Andrey, Galkin, Nikolay, Poliakov, Maxim, Volkova, Lidiya, Dudin, Alexander
Subject Terms: reactive epitaxy, crystal structure, эпитаксия, реактивная эпитаксия, epitaxy, silicon, Seebeck coefficient, power factor, фактор мощности, импульсное осаждение, кремний, микроскопия, transport properties, microscopy, пленки, films, pulsed deposition, силицид магния, magnesium silicide, кристаллическая структура, коэффициент Зеебека, транспортные свойства
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14Academic Journal
Subject Terms: термическая обработка, порог перколяции, температурная зависимость, микротвердость, ширина дифракционной линии, электропроводность, подвижность носителей заряда, коэффициент Холла, коэффициент Зеебека, heat treatment, percolation threshold, temperature dependence, microhardness, diffraction line width, electroconductivity, charge carrier mobility, Hall coefficient, Seebeck coefficient
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Relation: Рогачева Е. И. Особенности концентрационных зависимостей структурных и термоэлектрических свойств в твердых растворах PbTe–PbSe / Е. И. Рогачева, О. С. Водорез // Термоэлектричество. – 2013. – № 2. – С. 66-79.; http://repository.kpi.kharkov.ua/handle/KhPI-Press/52175
Availability: http://repository.kpi.kharkov.ua/handle/KhPI-Press/52175
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15Academic Journal
Authors: Каримов, Х., Ахмедов, Х., Абид, М., Мехран, Башир, Али, М., Шафик, У.
Subject Terms: ДАТЧИК, ГРАДИЕНТ ТЕМПЕРАТУРЫ, УГЛЕРОДНЫЕ НАНОТРУБКИ, НАПРЯЖЕНИЕ, ТОК, КОЭФФИЦИЕНТ ЗЕЕБЕКА
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16
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17Academic Journal
Subject Terms: коэффициент Зеебека, электропроводность, теплопроводность, концентрационные аномалии
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Relation: Водорез О. С. Влияние прессования на сыойства твердых растворов PbTe–PbSe / О. С. Водорез, Е. И. Рогачева // Науковий вісник Ужгородського університету. Сер. : Фізика = Uzhhorod University Scientific Herald. Ser. : Physics. – 2009. – Вип. 24. – С. 217-222.; http://repository.kpi.kharkov.ua/handle/KhPI-Press/52166
Availability: http://repository.kpi.kharkov.ua/handle/KhPI-Press/52166
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18Academic Journal
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19Academic Journal
Subject Terms: ширина дифракционной линии, heat treatment, diffraction line width, charge carrier mobility, Seebeck coefficient, термическая обработка, подвижность носителей заряда, Hall coefficient, порог перколяции, коэффициент Холла, электропроводность, percolation threshold, microhardness, микротвердость, electroconductivity, temperature dependence, коэффициент Зеебека, температурная зависимость
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20Academic Journal
Source: Доклады Академии наук Республики Таджикистан.
Subject Terms: ДАТЧИК, ГРАДИЕНТ ТЕМПЕРАТУРЫ, УГЛЕРОДНЫЕ НАНОТРУБКИ, НАПРЯЖЕНИЕ, ТОК, КОЭФФИЦИЕНТ ЗЕЕБЕКА
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