Geodesic
Morphology and phase composition of nanostructured carbon coatings, formed on the sublayer based on polytetrafluoroethylene and lead formate
Problemy fiziki, matematiki i tehniki, no. 4 (2021), pp. 38-44.

Voir la notice de l'article provenant de la source Math-Net.Ru

The features of the morphology and phase composition of carbon coatings deposited on sublayers based on polytetrafluoroethylene and lead formate of various compositions have been determined. The effect of the mass ratio of the components of the initial target used for the deposition of the sublayer and the heat treatment of carbon coatings on their morphology and phase composition has been established. The efficiency of using metal oxides and carbonized polymer layers for a given change in the phase composition and relief of carbon coatings is estimated.
Keywords: carbon coatings, lead, polytetrafluoroethylene, carbonation, morphology
Mots-clés : phase composition. 
@article{PFMT_2021_4_a5,
     author = {A. S. Rudenkov},
     title = {Morphology and phase composition of nanostructured carbon coatings, formed on the sublayer based on polytetrafluoroethylene and lead formate},
     journal = {Problemy fiziki, matematiki i tehniki},
     pages = {38--44},
     publisher = {mathdoc},
     number = {4},
     year = {2021},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/PFMT_2021_4_a5/}
}
TY  - JOUR
AU  - A. S. Rudenkov
TI  - Morphology and phase composition of nanostructured carbon coatings, formed on the sublayer based on polytetrafluoroethylene and lead formate
JO  - Problemy fiziki, matematiki i tehniki
PY  - 2021
SP  - 38
EP  - 44
IS  - 4
PB  - mathdoc
UR  - http://geodesic.mathdoc.fr/item/PFMT_2021_4_a5/
LA  - ru
ID  - PFMT_2021_4_a5
ER  - 
%0 Journal Article
%A A. S. Rudenkov
%T Morphology and phase composition of nanostructured carbon coatings, formed on the sublayer based on polytetrafluoroethylene and lead formate
%J Problemy fiziki, matematiki i tehniki
%D 2021
%P 38-44
%N 4
%I mathdoc
%U http://geodesic.mathdoc.fr/item/PFMT_2021_4_a5/
%G ru
%F PFMT_2021_4_a5
A. S. Rudenkov. Morphology and phase composition of nanostructured carbon coatings, formed on the sublayer based on polytetrafluoroethylene and lead formate. Problemy fiziki, matematiki i tehniki, no. 4 (2021), pp. 38-44. http://geodesic.mathdoc.fr/item/PFMT_2021_4_a5/

[1] A. Dasgupta et al., “Nanostructured carbon materials for enhanced nitrobenzene adsorption: Physical vs. chemical surface properties”, Carbon, 139 (2018), 833–844 | DOI

[2] A.V. Rogachev et al., “Features of the formation of nanoparticles based on copper inthin-layer systems”, Applied Surface Science, 317 (2014), 449–456 | DOI

[3] F.E. Kennedy et al., “Tribological behavior of hard carbon coatings on steel substrates”, Wear, 255 (2003), 854–858 | DOI

[4] A. Hosseinpour et al., “Recent advances and future perspectives for carbon nanostructures reinforced organic coating for anti-corrosion application”, Surfaces and Interfaces, 23 (2021), 100994 | DOI

[5] K. NowakowskaLangier et al., “Dependence of the specific features of two PAPVD methods: Impulse Plasma Deposition (IPD) and Pulsed Magnetron Sputtering (PMS) on the structure of Fe-Cu alloy layers”, Applied Surface Science, 275 (2013), 14–18 | DOI

[6] Z. Wang, Q-Z. Zhao, “Friction reduction of steel by laserinduced periodic surface nanostructures with atomic layer deposited TiO$_2$ coating”, Surface and Coatings Technology, 344 (2018), 269–275 | DOI

[7] X. Yang et al., “A double layer nanostructure SiC coating for anti-oxidation protection of carbon/carbon composites prepared by chemical vapor reaction and chemical vapor deposition”, Ceramics International, 39 (2013), 5053–5062 | DOI

[8] A.A. Rogachev et al., “Molecular structure, optical, electrical and sensing properties of PANI-based coatings with silver nanoparticles deposited from the active gas phase”, Applied Surface Science, 351 (2015), 811–818 | DOI

[9] C. Donnet, A. Erdemir, Tribology of Diamond-like Carbon Films: Fundamentals and Applications, Springer Science Business Media, 2007, 680 pp.

[10] A.C. Ferrari, “Diamond-like carbon for magnetic storage disks”, Surface and Coatings Technology, 180–181 (2004), 190–206 | DOI

[11] W. Yang, Y. Feng, W. Chu, “Catalytic chemical vapor deposition of methane to carbon nanotubes: copper promote defect of Ni/MgO catalysts”, Journal of Nanotechnology, 8 (2014), 547030–547035

[12] M. He et al., “Growth Mechanism of Single-Walled Carbon Nanotubes on Iron-Copper Catalyst and Chirality Studies by Electron Diffraction”, Chemistry Materials, 24 (2012), 1796–1801 | DOI

[13] Yu.A. Panshin, S.G. Malkevich, Ts.S. Dunaevskaya, Ftoroplasty, Khimiya, M., 1978, 231 pp.

[14] A.C. Ferrari et al., “Stress reduction and bond stability during thermal annealing of tetrahedral amorphous carbon”, Journal of Applied Physics, 85 (1999), 7191–7197 | DOI

[15] J. Rumble (ed.), CRC Handbook of Chemistry and Physics, Taylor Francis Group, 2021, 1624 pp.

[16] Zhubo Liu, Bing Zhou, A.V. Rogachev, M.A. Yarmolenko, “Growth feature of PTFE coatings on rubber substrate by low-energy electron beam dispersion”, Polymers for Advanced Technologies, 27 (2016), 823–829 | DOI

[17] Beibei Li et al., “Features of electron beam deposition of polymer coatings with the prolonged release of the drug component”, Materials Science Engineering C, 110 (2020), 110730 | DOI

[18] I. Dekhant (red.), Infrakrasnaya spektroskopiya polimerov, Khimiya, M., 1972, 472 pp.

[19] J. Robertson, E.P. O'Reilly, “Electronic and atomic structure of amorphous carbon”, Physical Review B, 35 (1987), 2946–2957 | DOI

[20] A.S. Ferrari, J. Robertson, “Interpretation of Raman spectra of disordered and amorphous carbon”, Physical Review B, 61 (2000), 4095–4107 | DOI

[21] J. Shwan et al., “Raman spectroscopy on amorphous carbon films”, Journal of Applied Physics, 80 (1996), 440–447 | DOI

[22] R.W. Bormett et al., “Ultraviolet Raman spectroscopy characterizes chemical vapor deposition diamond film growth and oxidation”, Journal of Applied Physics, 77 (1995), 5916–5923 | DOI