Corrosion Resistance and Structure of Cr−O−N Coatings Formed in Vacuum Arc Plasma Fluxes With PIIID

Alexandr Kuprin; Hanna Rostova; Elena Reshetnyak; Bogdan Warcholiński; Adam Gilewicz; Ilya Klimenko; Konrad Trzciński; Maria Gazda; Jacek Ryl; Sawczak Mirosław

doi:10.1002/maco.202414543

Corrosion Resistance and Structure of Cr−O−N Coatings Formed in Vacuum Arc Plasma Fluxes With PIIID

Abstrakt

Cr−O−N-based vacuum arc coatings are very promising for the wear and corrosion protection of various steel parts. The aim of the work was to determine the effect of frequency and amplitude of the pulsed bias voltage (UB) on the elemental and phase composition, mechanical, and corrosion properties of Cr−O−N coatings. They have an amorphous structure with embedded nanosized solid solution crystallites based on CrN with a cubic structure and Cr2O3 with a rhombohedral structure. The increase in the bias voltage results in a reduction in the grain size of the Cr2O3 and CrN phases by about four times to about 5 nm, as well as a change in the CrN phase content in the coating. The lattice parameter increases slightly for the Cr2O3 phase but decreases for the CrN phase. The increase in the pulse frequency results in an increase in the CrN phase content in the coating and the lattice constant of both phases and a slight decrease in the crystallite size. The hardness of Cr−O−N coatings slightly increased with the UB from 26 ± 1 GPa (DC) to 28 ± 1 GPa (−300 V, pulsed), and the elastic modulus ranges from 290 to 310 GPa. The greatest changes were observed in corrosion resistance. With an increase in the bias voltage and pulse frequency, the corrosion current of Cr−O−N coatings on steel in 3% NaCl solution decreased by three orders of magnitude compared to coatings deposited at DC voltage and by five orders of magnitude compared to the base steel. Therefore, the use of a pulsed bias voltage with a frequency of at least 10 kHz and an amplitude of 700 V can significantly increase the corrosion resistance of Cr−O−N coatings on steel substrates.

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Autorzy (10)

Alexandr Kuprin
- Kharkiv Institute of Physics and Technology
Hanna Rostova
- Kharkiv Institute of Physics and Technology
Elena Reshetnyak
- Kharkiv Institute of Physics and Technology
Bogdan Warcholiński
- Politechnika Koszalińska
Adam Gilewicz
- Politechnika Koszalińska
Ilya Klimenko
- Kharkiv Institute of Physics and Technology
Konrad Trzciński dr inż.
Maria Gazda prof. dr hab. inż.
Jacek Ryl dr hab. inż.
Sawczak Mirosław dr hab. inż.
- Instytut Maszyn Przepływowych PAN

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Kategoria:

Publikacja w czasopiśmie

Typ:

artykuły w czasopismach dostępnych w wersji elektronicznej [także online]

Opublikowano w:

MATERIALS AND CORROSION-WERKSTOFFE UND KORROSION
ISSN: 0947-5117

Język:

angielski

Rok wydania:

2025

Opis bibliograficzny:

Kuprin A., Rostova H., Reshetnyak E., Warcholiński B., Gilewicz A., Klimenko I., Trzciński K., Gazda M., Ryl J., Mirosław S., Corrosion Resistance and Structure of Cr−O−N Coatings Formed in Vacuum Arc Plasma Fluxes With PIIID, MATERIALS AND CORROSION-WERKSTOFFE UND KORROSION, 2025,10.1002/maco.202414543

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