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Dependence of mechanical and tribotechnical properties of multilayered TiN/ZrN coatings on deposition

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Warianty tytułu
PL
Zależność właściwości mechanicznych i trybologicznych wielowarstwowych powłok TiN/ZrN od warunków osadzania
Języki publikacji
EN
Abstrakty
EN
C-PVD method (vacuum arc deposition of a cathodes) was used for deposition of multilayered coatings, based on TiN/ZrN systems, with different thickness of bilayers. Total thickness of the coatings was 11 – 19 μm, thickness of bilayers varied from 39 to 305 nm for different samples depending on deposition conditions. Microstructure of the coatings, mechanical and tribotechnical properties, and wear resistance were explored. Influence of the bilayer thickness on such properties of the coatings, as hardness, elasticity modulus, wear resistance and wear ratio were explored.
PL
Metoda C-PVD (napylanie próżniowo-łukowe katod) została użyta do osadzania wielowarstwowych powłok, na bazie układów TiN/ZrN o zmiennej grubości pojedynczych warstw. Całkowita grubość powłoki wynosiła 11 – 19 μm, przy czym grubość pojedynczych warstw wahała się od 39 do 305 nm dla różnych próbek zależnie od warunków osadzania. Zbadano mikrostrukturę powłok, właściwości mechaniczne i trybologiczne oraz odporność na zużycie.
Rocznik
Strony
233--236
Opis fizyczny
Bibliogr. 33 poz., rys., tab., wykr.
Twórcy
autor
  • Sumy State University, Sumy,Ukraine
  • National Scientific Centre “KhFTI”, Kharkiv, Ukraine
  • East- Kazakhstan Technical University, Ust’-Kamenogorsk, Kazakhstan
  • East- Kazakhstan Technical University, Ust’-Kamenogorsk, Kazakhstan
  • East- Kazakhstan Technical University, Ust’-Kamenogorsk, Kazakhstan
  • Lublin University of Technology, Mechanical Department, Institute of Technological Systems of Information, Lublin, Poland
autor
  • University of Life Sciences in Lublin, Department of Technology Fundamentals, Lublin, Poland
autor
  • Lublin University of Technology, Department of Electrical Devices and High Voltage Technology, Lublin, Poland
Bibliografia
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  • [7] Vladescu A., Kiss A., Popescu A., Braic M., Balaceanu M., Braic V. et al., Influence of bilayer period on the characteristics of nanometre-scale ZrN/TiAlN multilayers, J. Nanosci. Nanotechnol. 8 (2008), 717-738.
  • [8] Wen M., Meng Q., Hu C., Au T., Su Y., Yu W. et al., Structure and mechanical properties of σ-NbN/SiNx and σ´-NbN/SiNx nano-multilayer films deposited by reactive magnetron sputtering, Surf. Coat. Technol. 203 (2009), 1702-1708.
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  • [12] Zhang Guojun, Fan Tianxiang, Wang Tao, Chen Hailin, Microstructure, mechanical and tribological behavior of MoN/SiNx multilayer coatings prepared by magnetron sputtering, Appl. Surf. Sci. 274 (2013), 231–236.
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  • [18] Beresnev V.M., Bondar O.V., Postol’nyi B.A., Lisovenko M.A., Abadias G., Chartier P, Kolesnikov D.A., Borisyuk V.N., Mukushev B.A., Zhollybekov B.R., Andreev A.A. Comparison of Tribological Characteristics of Nanostructured TiN, MoN, and TiN/MoN ArcPVD Coatings, J. Frict. Wear. 35, no 5 (2014), 374-382.
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  • [20] Misaelides P., Hatzidimitriou A., Noli F., Pogrebnjak A.D., Tyurin Y.N., Kosionidis S. Preparation, Characterization, and corrosion behavior of protective coatings on stainless steel samples deposited by plasma detonation techniques, Surf. Coat. Tech. 180-181 (2004), 290-296.
  • [21] Pogrebnjak A.D., Proskurovskii D.I., Modification of metal surface layer properties using pulsed electron beams, Phys. Stat. Solidi (A) Appl. Res. 145, no1 (1994), 9-49.
  • [22] Lavrentiev V.I., Pogrebnjak A.D., High-dose Ion Implantation into Metals, Surf. Coat. Tech. 99 (1-2) (1998), 24-32.
  • [23] Pogrebnjak A.D., Bakharev O.G., Pogrebnjak Jr N.A., Tsvintarnaya Yu.V., Shablja V.T., Sandrik R., Zecca A., Certain features of high-dose and intensive implantation of Al ions in iron, Phys. Let. A, 265, no 3, (2000), 225-232.
  • [24] Kołtunowicz T.N., Żukowski P., Bondariev V., Fedotova J.A., Fedotov A.K., The effect of annealing on the impedance of (FeCoZr)x(CaF2)(100-x) nanocomposite films produced by the ion-beam sputtering in vacuum, Vacuum (2015) DOI: 10.1016/j.vacuum.2015.01.030
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  • [26] Koltunowicz T.N., Zhukowski P., Bondariev V., Saad A., Fedotova J.A., Fedotov A.K., Milosavljevic M., Kasiuk J.V., Enhancement of negative capacitance effect in (FeCoZr)x(CaF2)(100-x) nanocomposite films deposited by ion beam sputtering in argon and oxygen atmosphere, J. Alloys Compd. 615, no 1 (2014), S361-S365.
  • [27] Bratushka S.N., Opielak M., Liscak S., Structure and properties of Co-Cr coatings after a pulsed jet treatment, Przegl. Elektrotech. 88, no 10A (2012), 314-318.
  • [28] Pogrebnjak A.D., Bagdasaryan A.A., Yakushchenko I.V., Beresnev V.M., The structure and properties of high-entropy alloys and nitride coatings based on them, Rus. Chem. Rev. 83, no 11 (2014), 1027-1061.
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  • [31] Kirik G.V., Kozak C., Opielak M., Protective coatings based on Zr-Ti-Si-N their physical and mechanical properties and phase composition, Przegl. Elektrotech. 88, no10A (2012), 319-321.
  • [32] Pogrebnjak A.D., Kravchenko Yu.A., Kislitsyn S.B., Ruzimov Sh.M., Noli F., Misaelides P., Hatzidimitriou A., TiN/Cr/Al2O3 and TiN/Al2O3 hybrid coatings structure features and properties resulting from combined treatment, Surf. Coat. Technol. 201, no 6 (2006), 2621-2632.
  • [33] Musil J., Hard nanocomposite coatings: thermal stability, oxidation resistance and toughness, Surf. Coat. Technol. 207 (2012), 50-65.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c8aab329-ee5c-4bae-8ac2-51c767b94466
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