A Carbon Nanostructure for a Thermoelectric Generator

We demonstrate that it is technologically possible to obtain graphite-like films which can be used for the creation of a thermoelectric generator. The proposed technology ensures uniformity and rather small thickness of these films and allows them to be formed on a diamond-like film substrate with d...

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Veröffentlicht in:	Technical physics letters 2019-04, Vol.45 (4), p.339-342
Hauptverfasser:	Rabchinskii, M. K., Eidelman, E. D., Vinogradov, A. Ya, Grudinkin, S. A., Dideikin, A. T.
Format:	Artikel
Sprache:	eng
Schlagworte:	Carbon Classical and Continuum Physics CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY DEPOSITION Diamond films DIAMONDS DIFFUSION DRAG ELECTRON-PHONON COUPLING ELECTROPHORESIS GRAPHITE INTERFACES Nanostructure NANOSTRUCTURES Phonon drag Phonons Physics Physics and Astronomy Substrates THERMOELECTRIC GENERATORS Thermoelectricity Thickness THIN FILMS
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container_end_page	342
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container_title	Technical physics letters
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creator	Rabchinskii, M. K. Eidelman, E. D. Vinogradov, A. Ya Grudinkin, S. A. Dideikin, A. T.
description	We demonstrate that it is technologically possible to obtain graphite-like films which can be used for the creation of a thermoelectric generator. The proposed technology ensures uniformity and rather small thickness of these films and allows them to be formed on a diamond-like film substrate with deposited contacts at acceptable interface. Measurements show that the electron-phonon drag effect in this system ensures thermo-emf values about 100 times as large as those provided by the diffusion process. Arrangement of the graphite-like material on a diamond-like film substrate also favors increase in the thermo-emf, which is a manifestation of the electron–ballistic phonon drag. It is established that conditions necessary for the creation of a thermoelectric generator can be achieved based on the proposed carbon nanostructures.
doi_str_mv	10.1134/S1063785019040138
format	Article
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subjects	Carbon Classical and Continuum Physics CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY DEPOSITION Diamond films DIAMONDS DIFFUSION DRAG ELECTRON-PHONON COUPLING ELECTROPHORESIS GRAPHITE INTERFACES Nanostructure NANOSTRUCTURES Phonon drag Phonons Physics Physics and Astronomy Substrates THERMOELECTRIC GENERATORS Thermoelectricity Thickness THIN FILMS
title	A Carbon Nanostructure for a Thermoelectric Generator
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