Electrically conductive ceramics based on Al – AlN – TiB2

Karpov, A.; Kovalev, D.; Borovinskaya, I.; Sytchev, A.

doi:10.31857/S004036440002716-1

Home

Teplofizika vysokikh temperatur

Issue 4

Electrically conductive ceramics based on Al – AlN – TiB2

Annotation
Reviews
References

Electrically conductive ceramics based on Al – AlN – TiB2

PII

S004036440002716-1-1

DOI

10.31857/S004036440002716-1

Publication type

Article

Status

Published

Authors

A. Karpov

Affiliation: Institute of Structural Macrokinetics and Problems of Materials Science RAS
Address: Russian Federation

D. Kovalev

Affiliation: Institute of Structural Macrokinetics and Problems of Materials Science RAS
Address: Russian Federation

I. Borovinskaya

Affiliation: Institute of Structural Macrokinetics and Problems of Materials Science RAS
Address: Russian Federation

A. Sytchev

Affiliation: Institute of Structural Macrokinetics and Problems of Materials Science RAS
Address: Russian Federation

Journal name

Teplofizika vysokikh temperatur

Edition

Volume 56 Issue 4

Pages

543-547

Abstract

Keywords

Acknowledgment

The work was performed using the instrumental base of the ISMAN Distributed Sharing Center (RSCP ISMAN).

Received

26.12.2018

Publication date

26.12.2018

Cite Download pdf To download PDF you should sign in

GOST	Karpov A., Kovalev D., Borovinskaya I., Sytchev A. Electrically conductive ceramics based on Al – AlN – TiB2 // Teplofizika vysokikh temperatur – 2018. – V. 56. – Issue 4 C. 543-547 [Electronic resource]. URL: http://ras.jes.su/tvt/s004036440002716-1-1-en (circulation date: 25.04.2024). DOI: 10.31857/S004036440002716-1
MLA	Karpov, A., Kovalev, D., Borovinskaya, I., Sytchev, A. "Electrically conductive ceramics based on Al – AlN – TiB2." Teplofizika vysokikh temperatur 56.4 (2018):543-547. DOI: 10.31857/S004036440002716-1
APA	Karpov A., Kovalev D., Borovinskaya I., Sytchev A. (2018). Electrically conductive ceramics based on Al – AlN – TiB2. Teplofizika vysokikh temperatur 56(4), pp.543-547 DOI: 10.31857/S004036440002716-1

Размещенный ниже текст является ознакомительной версией и может не соответствовать печатной

Readers community rating: votes 0

1. Weimer W. Carbide, Nitride, and Boride Materials: Synthesis and Processing. London: Chapman & Hall, 1997. P. 228.

2. Zhang G.J, Jin Z. Z. Reactive Synthesis of AlN/TiB2 // Composite. Ceram. Int. 1996. V. 22. P. 143. https://doi.org/10.1016/0272–8842 (95)00070–4

3. Xu G-F., Carmel Y., Olorunyolemi T., Lloyd I. K., Wilson O. C. Microwave Sintering and Properties of AlN/TiB2 Composites // J. Mater. Res. 2003. V. 18. Iss. 1. P. 66. https://doi.org/10.1557/JMR.2003.0010

4. Li L.-H., Kim H.-E., Kang E. S. Sintering and Mechanical Properties of Titanium Diboride with Aluminum Nitride as a Sintering Aid // J. Eur. Ceram. Soc. 2002. V. 22. № 6. P. 973. https://doi.org/10.1016/S0955–2219 (01)00403–4

5. Kim H.-J., Choi H.-J., Lee J-G. Mechanical Synthesis and Pressureless Sintering of TiB2–AlN // Composit. J. Amer. Ceram. Soc. 2002. V. 85. № 4. P. 1022. https://doi.org/10.1111/j.1151–2916.2002.tb00216.x

6. Fonseca Pecanha Jr.L.A., Simao L., Skury L. D., Oliveira M. P., Bolzan L. T., Monteiro S. N. Harder and Denser TiB2–AlN Ceramic Composites Processed by Spark Plasma Sintering // Mater. Sci. Forum. 2016. V. 869. P. 52.

7. Merzhanov A.G., Borovinskaya I. P. Samorasprostranyayuschijsya vysokotemperaturnyj sintez tugoplavkikh neorganicheski soedinenij // DAN SSSR. 1972. T. 204. № 2. C. 366.

8. Zhou L., Zheng Y., Du Sh. Fabrication of BN-AlN-TiB2 Compound Conductive Ceramics by Self-Propagating High Temperature Synthesis and Hot Isostatic Pressing // Key Eng. Mater. 2007. V. 336–338. P. 786.

9. Bunin V.A., Karpov A. V., Senkovenko M. Yu. Osobennosti sinteza, struktury i svojstva keramiki v sisteme TiB2–AlN // Neorg. materialy. 2002. T. 38. № 7. S. 892.

10. Borovinskaya I.P., Bunin V. A., Vishnyakova G. A., Karpov A. V. Some Specific Features of Synthesis and Characteristics of (TiB2–AlN–BN)-Based Ceramic Materials // Int. J. SHS. 1999. V. 8. № 4. P. 451.

11. Mattia D., Desmaison-Brut M., Tetard D., Desmaison J. Wetting of HIP AlN–TiB2 Ceramic Composites by Liquid Metals and Alloys // J. Europ. Ceramic Society. 2005. V. 25. P. 1797. https://doi.org/10.1016/j.jeurceramsoc.2004.12.012

12. Akopov F.A., Borovkova L. B. Vysokoogneupornyj ehlektroprovodnyj keramicheskij material na osnove dioksida tseriya // TVT. 2011. T. 49. № 6. S. 893.

13. Karpov A.V., Morozov Yu. G., Bunin V. A., Borovinskaya I. P. Vliyanie oksida ittriya na ehlektroprovodnost' nitridnoj SVS-keramiki // Neorg. materialy. 2002. T. 38. № 6. S. 762.

14. Khomenko I.O., Mukasyan A. S., Ponomarev V. I., Borovinskaya I. P., Merzhanov A. G. Dynamic of Phase Forming Processes in the Combustion of Metal–Gas Systems // Combust. Flame. 1993. V. 92. P. 201.

15. Andrievskij R.A., Kalinnikov G. V., Kobelev N. P., Sojfer Ya. M., Shtanskij D. V. Struktura i fiziko-mekhanicheskie svojstva nanostrukturnykh boronitridnykh plenok // FTT. 1997. T. 39. № 10. S. 1859.

16. Murlieva Zh. Kh., Iskhakov M. Eh., Palchaev D. K., Faradzheva M. P., Chernykh D. G. Temperaturnaya zavisimost' ehlektrosoprotivleniya splavov, obuslovlennaya dinamicheskim i staticheskim besporyadkami // TVT. 2012. T. 50. № 5. S. 644.