Investigation of multilayer superhard Ti-Hf-Si-N/NbN/AI2O3 coatings for high performance protection

A. D. Pogrebnjak; A. S. Kaverina; V. M. Beresnev; Y. Takeda; K. Oyoshi; H. Murakami; A. P. Shypylenko; M. G. Kovaleva; M. S. Prozorova; O. V. Kolisnichenko; B. Zholybekov; D. A. Kolesnikov

Investigation of multilayer superhard Ti-Hf-Si-N/NbN/AI₂O₃ coatings for high performance protection

A. D. Pogrebnjak, A. S. Kaverina, V. M. Beresnev, Y. Takeda, K. Oyoshi, H. Murakami, A. P. Shypylenko, M. G. Kovaleva, M. S. Prozorova, O. V. Kolisnichenko, B. Zholybekov, D. A. Kolesnikov

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

In this work we first obtained multilayered solid micro-and nanostructured coatings produced by several deposition techniques based on Ti-Hf-Si-N/NbN/Al₂O₃ on the steel substrate. It was found that the investigated coatings, along with high hardness (H) from 47 to 56 GPa and modulus of elasticity (E) from 435 to 570 GPa, the plasticity index We = (0.08-0.11), have a fairly low coefficient of friction (μ) which varies from 0.02 to 0.001 for a given mode of deposition. It is also shown that these multilayered coatings have high thermal stability (above 1000C). The annealing temperature up to 1070°C in a vacuum about 10^-2Pa showed that the coating in the upper layers consisting of Ti-Hf-Si-N/NbN the size of nanograins increases from 25 to 56 nm (for the Ti-Hf-Si-N) and from 14-15 to 35-37 nm for NbN. The increase of steel microhardness at the "coating - substrate" interface, is due to the presence of the hardening near the border with coating formed as a result of impact during abrasive blasting and deposition of coating.

Original language	English
Title of host publication	Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials
Subtitle of host publication	Ceramic Engineering and Science Proceesings
Editors	Tatsuki Ohji, Mrityunjay Singh, Sanjay Mathur
Publisher	American Ceramic Society
Pages	163-171
Number of pages	9
Edition	6
ISBN (Electronic)	9781119031185, 9781119040200, 9781119040262, 9781119040279, 9781119040286, 9781119040385, 9781119040439
Publication status	Published - 2014
Externally published	Yes
Event	Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials - 38th International Conference on Advanced Ceramics and Composites, ICACC 2014 - Daytona Beach, United States Duration: 2014 Jan 26 → 2014 Jan 31

Publication series

Name	Ceramic Engineering and Science Proceedings
Number	6
Volume	35
ISSN (Print)	0196-6219

Other

Other	Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials - 38th International Conference on Advanced Ceramics and Composites, ICACC 2014
Country/Territory	United States
City	Daytona Beach
Period	14/1/26 → 14/1/31

ASJC Scopus subject areas

Ceramics and Composites
Materials Chemistry

Cite this

Pogrebnjak, A. D., Kaverina, A. S., Beresnev, V. M., Takeda, Y., Oyoshi, K., Murakami, H., Shypylenko, A. P., Kovaleva, M. G., Prozorova, M. S., Kolisnichenko, O. V., Zholybekov, B., & Kolesnikov, D. A. (2014). Investigation of multilayer superhard Ti-Hf-Si-N/NbN/AI₂O₃ coatings for high performance protection. In T. Ohji, M. Singh, & S. Mathur (Eds.), Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials: Ceramic Engineering and Science Proceesings (6 ed., pp. 163-171). (Ceramic Engineering and Science Proceedings; Vol. 35, No. 6). American Ceramic Society.

Investigation of multilayer superhard Ti-Hf-Si-N/NbN/AI₂O₃ coatings for high performance protection. / Pogrebnjak, A. D.; Kaverina, A. S.; Beresnev, V. M. et al.
Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials: Ceramic Engineering and Science Proceesings. ed. / Tatsuki Ohji; Mrityunjay Singh; Sanjay Mathur. 6. ed. American Ceramic Society, 2014. p. 163-171 (Ceramic Engineering and Science Proceedings; Vol. 35, No. 6).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Pogrebnjak, AD, Kaverina, AS, Beresnev, VM, Takeda, Y, Oyoshi, K, Murakami, H, Shypylenko, AP, Kovaleva, MG, Prozorova, MS, Kolisnichenko, OV, Zholybekov, B & Kolesnikov, DA 2014, Investigation of multilayer superhard Ti-Hf-Si-N/NbN/AI₂O₃ coatings for high performance protection. in T Ohji, M Singh & S Mathur (eds), Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials: Ceramic Engineering and Science Proceesings. 6 edn, Ceramic Engineering and Science Proceedings, no. 6, vol. 35, American Ceramic Society, pp. 163-171, Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials - 38th International Conference on Advanced Ceramics and Composites, ICACC 2014, Daytona Beach, United States, 14/1/26.

Pogrebnjak AD, Kaverina AS, Beresnev VM, Takeda Y, Oyoshi K, Murakami H et al. Investigation of multilayer superhard Ti-Hf-Si-N/NbN/AI₂O₃ coatings for high performance protection. In Ohji T, Singh M, Mathur S, editors, Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials: Ceramic Engineering and Science Proceesings. 6 ed. American Ceramic Society. 2014. p. 163-171. (Ceramic Engineering and Science Proceedings; 6).

Pogrebnjak, A. D. ; Kaverina, A. S. ; Beresnev, V. M. et al. / Investigation of multilayer superhard Ti-Hf-Si-N/NbN/AI₂O₃ coatings for high performance protection. Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials: Ceramic Engineering and Science Proceesings. editor / Tatsuki Ohji ; Mrityunjay Singh ; Sanjay Mathur. 6. ed. American Ceramic Society, 2014. pp. 163-171 (Ceramic Engineering and Science Proceedings; 6).

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abstract = "In this work we first obtained multilayered solid micro-and nanostructured coatings produced by several deposition techniques based on Ti-Hf-Si-N/NbN/Al2O3 on the steel substrate. It was found that the investigated coatings, along with high hardness (H) from 47 to 56 GPa and modulus of elasticity (E) from 435 to 570 GPa, the plasticity index We = (0.08-0.11), have a fairly low coefficient of friction (μ) which varies from 0.02 to 0.001 for a given mode of deposition. It is also shown that these multilayered coatings have high thermal stability (above 1000C). The annealing temperature up to 1070°C in a vacuum about 10-2Pa showed that the coating in the upper layers consisting of Ti-Hf-Si-N/NbN the size of nanograins increases from 25 to 56 nm (for the Ti-Hf-Si-N) and from 14-15 to 35-37 nm for NbN. The increase of steel microhardness at the {"}coating - substrate{"} interface, is due to the presence of the hardening near the border with coating formed as a result of impact during abrasive blasting and deposition of coating.",

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AU - Takeda, Y.

AU - Oyoshi, K.

AU - Murakami, H.

AU - Shypylenko, A. P.

AU - Kovaleva, M. G.

AU - Prozorova, M. S.

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N2 - In this work we first obtained multilayered solid micro-and nanostructured coatings produced by several deposition techniques based on Ti-Hf-Si-N/NbN/Al2O3 on the steel substrate. It was found that the investigated coatings, along with high hardness (H) from 47 to 56 GPa and modulus of elasticity (E) from 435 to 570 GPa, the plasticity index We = (0.08-0.11), have a fairly low coefficient of friction (μ) which varies from 0.02 to 0.001 for a given mode of deposition. It is also shown that these multilayered coatings have high thermal stability (above 1000C). The annealing temperature up to 1070°C in a vacuum about 10-2Pa showed that the coating in the upper layers consisting of Ti-Hf-Si-N/NbN the size of nanograins increases from 25 to 56 nm (for the Ti-Hf-Si-N) and from 14-15 to 35-37 nm for NbN. The increase of steel microhardness at the "coating - substrate" interface, is due to the presence of the hardening near the border with coating formed as a result of impact during abrasive blasting and deposition of coating.

AB - In this work we first obtained multilayered solid micro-and nanostructured coatings produced by several deposition techniques based on Ti-Hf-Si-N/NbN/Al2O3 on the steel substrate. It was found that the investigated coatings, along with high hardness (H) from 47 to 56 GPa and modulus of elasticity (E) from 435 to 570 GPa, the plasticity index We = (0.08-0.11), have a fairly low coefficient of friction (μ) which varies from 0.02 to 0.001 for a given mode of deposition. It is also shown that these multilayered coatings have high thermal stability (above 1000C). The annealing temperature up to 1070°C in a vacuum about 10-2Pa showed that the coating in the upper layers consisting of Ti-Hf-Si-N/NbN the size of nanograins increases from 25 to 56 nm (for the Ti-Hf-Si-N) and from 14-15 to 35-37 nm for NbN. The increase of steel microhardness at the "coating - substrate" interface, is due to the presence of the hardening near the border with coating formed as a result of impact during abrasive blasting and deposition of coating.

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