Physical Doping Nanocomposites with Carbon Nanostructures with High Electron Affinity
The fundamental scientific problem for micro- and nanoelectronics has been solved – methods for creating and investigating properties of physically doped materials with spatially inhomogeneous structure at the micro- and nanometer scale have been developed. For the application of functional nanocomp...
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Format: | Article |
Language: | English |
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IFSA Publishing, S.L.
2021-01-01
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Series: | Sensors & Transducers |
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Online Access: | https://sensorsportal.com/HTML/DIGEST/january_2021/Vol_248/P_3198.pdf |
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author | Philipp Vysikaylo Valeriy Mitin Vladimir Mashchenko |
author_facet | Philipp Vysikaylo Valeriy Mitin Vladimir Mashchenko |
author_sort | Philipp Vysikaylo |
collection | DOAJ |
description | The fundamental scientific problem for micro- and nanoelectronics has been solved – methods for creating and investigating properties of physically doped materials with spatially inhomogeneous structure at the micro- and nanometer scale have been developed. For the application of functional nanocomposite film coatings based on carbides of various transition metals structured by nanocarbon, for the first time in the world we developed a new technique for their plasma deposition on a substrate without the use of reaction gases (hydrocarbons such as propane, acetylene, etc.). We have created nanostructured film materials, including those with increased strength and wear resistance, heterogeneous at the nanoscale, physically doped with nanostructures - quantum traps for free electrons. We learned how to simultaneously spray (in a plasma of a stationary magnetron discharge) carbides and graphite from a special mosaic target (carbide + carbon) made mechanically Based on the analysis of experimental work, we have formulated the foundations of cumulative quantum mechanics capable of describing the unlimited cumulation of the Y-function of a quantum particle to the center in hollow spherically and cylindrically symmetric nanoscale quantum resonators. |
first_indexed | 2024-03-12T17:24:52Z |
format | Article |
id | doaj.art-c26b33de953045eaaa3b48b60acb7174 |
institution | Directory Open Access Journal |
issn | 2306-8515 1726-5479 |
language | English |
last_indexed | 2024-03-12T17:24:52Z |
publishDate | 2021-01-01 |
publisher | IFSA Publishing, S.L. |
record_format | Article |
series | Sensors & Transducers |
spelling | doaj.art-c26b33de953045eaaa3b48b60acb71742023-08-05T09:07:58ZengIFSA Publishing, S.L.Sensors & Transducers2306-85151726-54792021-01-0124811826Physical Doping Nanocomposites with Carbon Nanostructures with High Electron AffinityPhilipp Vysikaylo0Valeriy Mitin1Vladimir Mashchenko2Moscow State Regional UniversityMoscow State Regional UniversityMoscow State Regional UniversityThe fundamental scientific problem for micro- and nanoelectronics has been solved – methods for creating and investigating properties of physically doped materials with spatially inhomogeneous structure at the micro- and nanometer scale have been developed. For the application of functional nanocomposite film coatings based on carbides of various transition metals structured by nanocarbon, for the first time in the world we developed a new technique for their plasma deposition on a substrate without the use of reaction gases (hydrocarbons such as propane, acetylene, etc.). We have created nanostructured film materials, including those with increased strength and wear resistance, heterogeneous at the nanoscale, physically doped with nanostructures - quantum traps for free electrons. We learned how to simultaneously spray (in a plasma of a stationary magnetron discharge) carbides and graphite from a special mosaic target (carbide + carbon) made mechanically Based on the analysis of experimental work, we have formulated the foundations of cumulative quantum mechanics capable of describing the unlimited cumulation of the Y-function of a quantum particle to the center in hollow spherically and cylindrically symmetric nanoscale quantum resonators.https://sensorsportal.com/HTML/DIGEST/january_2021/Vol_248/P_3198.pdfphysical alloyingallotropic carbon nanostructurescoefficient of dry frictionwear and temperature resistance of nanocompositescharged layer |
spellingShingle | Philipp Vysikaylo Valeriy Mitin Vladimir Mashchenko Physical Doping Nanocomposites with Carbon Nanostructures with High Electron Affinity Sensors & Transducers physical alloying allotropic carbon nanostructures coefficient of dry friction wear and temperature resistance of nanocomposites charged layer |
title | Physical Doping Nanocomposites with Carbon Nanostructures with High Electron Affinity |
title_full | Physical Doping Nanocomposites with Carbon Nanostructures with High Electron Affinity |
title_fullStr | Physical Doping Nanocomposites with Carbon Nanostructures with High Electron Affinity |
title_full_unstemmed | Physical Doping Nanocomposites with Carbon Nanostructures with High Electron Affinity |
title_short | Physical Doping Nanocomposites with Carbon Nanostructures with High Electron Affinity |
title_sort | physical doping nanocomposites with carbon nanostructures with high electron affinity |
topic | physical alloying allotropic carbon nanostructures coefficient of dry friction wear and temperature resistance of nanocomposites charged layer |
url | https://sensorsportal.com/HTML/DIGEST/january_2021/Vol_248/P_3198.pdf |
work_keys_str_mv | AT philippvysikaylo physicaldopingnanocompositeswithcarbonnanostructureswithhighelectronaffinity AT valeriymitin physicaldopingnanocompositeswithcarbonnanostructureswithhighelectronaffinity AT vladimirmashchenko physicaldopingnanocompositeswithcarbonnanostructureswithhighelectronaffinity |