Prospects of nanotechnology and materials design on the basis of refractory compounds

As a matter of discussion, the prospects for the development of high-temperature ceramic materials science are considered. The paper provides a rationale for developing hetero-modulus ceramic composites as a possibility to implement the unique physicochemical properties of refractory compounds (carbides, nitrides, borides, etc.) under the conditions of their application at high and ultra-high temperatures. The prospects of nanotechnology-based approach to the preparation of similar materials in engineering practice are shown.

refractory compounds, hetero-modulus ceramics, ridge effect, MAX phases, graphene, 2D MXenes

1. Shabalin I.L. Advances in materials science of metals, ceramics, and composites at the turn of the millennium. Powder Metall. Met. Ceram. 2009. Vol. 48. Iss. 9—10. P. 610—612.

2. Shabalin I.L. Ultra-high temperature materials. Vol. I. Carbon (graphene/graphite) and refractory metals. Dordrecht, London: Springer Science, 2014.

3. Samsonov G.V., Obolonchik V.A. Frederic Henri Moissan, on the 120th anniversary of his birth. Powder Metall. Met. Ceram. 1972. Vol. 11. Iss. 9. P. 766—768.

4. Gnesin G.G. Materials scientists, engineers and inventors. Kiev: Logos, 2010 (In Russ.).

5. Gubanov V.A., Ivanovsky A.L., Zhukov V.P. Electronic structure of refractory carbides and nitrides. Cambridge: Cambridge University Press, 1994.

6. Upadhyaya G.S. Nature and properties of refractory carbides. Commack, New York: Nova Science, 1996.

7. Shabalin I.L. Ultra-high temperature materials. Vol. II. Refractory carbides I (Ta, Hf, Nb and Zr carbides). Dordrecht, London: Springer Science, 2018 (in press).

8. Spriggs G.E. A history of fine grained hardmetal. Int. J. Refract. Met. Hard Mater. 1995. Vol. 13. P. 241—255.

9. Kisliy P.S., Bodnaruk N.I., Borovikova M.S. Cermets. Kiev: Naukova dumka, 1985 (In Russ.).

10. Shabalin I.L., Wang Y., Krynkin A.V. et al. Physicomechanical properties of ultrahigh temperature heteromodulus ceramics based on group 4 transition metal carbides. Adv. Appl. Ceram. 2010. Vol. 109. Iss. 7. P. 405—415.

11. Jeitschko W., Nowotny H. Die kristallstruktur von Ti3SiC2 — ein neuer komplexcarbid-typ. Monatsh. Chem. 1967. Vol. 98. Iss. 2. P. 329—337.

12. Nowotny H. Strukturchemie einiger verbindungen der übergangsmetalle mit den elementen C, Si, Ge, Sn. Prog. Solid State Chem. 1970. Vol. 2. P. 27—70.

13. Barsoum M.W. MAX phases. Properties of machinable ternary carbides and nitrides. Weinheim: Wiley-VCH, 2013.

14. Hasselman D.P.H. Experimental and calculated Young’s moduli of zirconium carbide containing a dispersed phase of graphite. J. Am. Ceram. Soc. 1963. Vol. 46. Iss. 2. P. 103—104.

15. Hasselman D.P.H., Becher P.F., Mazdiyasni K.S. Analysis of the resistance of high-E, low-E brittle composites to failure by thermal shock. Z. Werkstofftech. 1980. Bd. 11. No. 3. S. 82—92.

16. Kendall E.G., Carnahan R.D., Rossi R.C. Hypereutectic carbides highly resistant to thermal shock. Space/Aeronautics. 1967. Vol. 47. Iss. 1. P. 132—133, 135.

17. Shabalin I.L., Beketov А.R., Vlasov V.G., Pakholkov V.V. To the problem of carbide-carbon composites manufacturing by hot pressing. In: Goryachee pressovanie. Kiev: IPM АN USSR, 1977. Pt. 2. P. 15—18 (In Russ.).

18. Kendall K. Control of cracks by interfaces in composites. Proc. R. Soc. Lond. 1975. Vol. 341. P. 409—428.

19. Kendall K. Transition between cohesive and interfacial failure in a laminate. Proc. R. Soc. Lond. 1975. Vol. 344. P. 287—302.

20. Cook J., Gordon J.E., Evans C.C., Marsh D.M. A mechanism for the control of crack propagation in all-brittle systems. Proc. R. Soc. Lond. 1964. Vol. 282. P. 508—520.

21. Hasselman D.P.H. Figures-of-merit for the thermal stress resistance of high-temperature brittle materials: a review. Ceramurg. Int. 1978. Vol. 4. Iss. 4. P. 147—150.

22. Hasselman D.P.H., Donaldson K.Y. Designing for severe thermal stresses. In: An introduction to ceramic engineering design. Westerville, OH: The American Ceramic Society, 2002. P. 177—198.

23. Shabalin I.L. Principles of property optimization and composition selection for hetero-modulus ceramics based on refractory carbides. In: Materials science of refractory compounds: achievements and problems: Proc. Int. conf. devoted to the 90th birthday anniversary of Acad. G.V. Samsonov (27—29 May 2008). Kiev: National Academy of Science of Ukraine, 2008. P. 9—10.

24. Shabalin I.L. TSR of hetero-modulus ceramics. In: Encyclopedia of thermal stresses. Dordrecht: Springer, 2014. Vol. 11. P. 6250—6255.

25. Harada Y. High strength hot-pressed metal carbide — graphite composites: Report NASA-CR-77114. Chicago, IL: IIT Research Institute, 1966.

26. Аndrievsky R.А., Lanin А.G., Rymashevsky G.А. Strength of refractory compounds. Moscow: Metallurgiya, 1974 (In Russ.).

27. Shabalin I.L., Tomkinson D.M., Shabalin L.I. High-temperature hot-pressing of titanium carbide — graphite hetero-modulus ceramics. J. Eur. Ceram. Soc. 2007. Vol. 27. Iss. 5. P. 2171—2181.

28. Shabalin I.L. «Ridge effect» in oxidation kinetics of hetero-modulus ceramics based on titanium carbide. Powder Metall. Met. Ceram. 2008. Vol. 47. Iss. 1—2. P. 137—150.

29. Shabalin I.L. Oxidation behaviour of hetero-modulus ceramics based on titanium carbide. In: Developments in strategic materials: Collection of papers 32nd Int. conf. on advanced ceramics and composites (Daytona Beach, FL, 27 Jan. — 1 Febr. 2008). N.Y.: John Wiley, 2009. P. 261—278.

30. Novoselov K.S., Geim A.K., Morozov S.V. et al. Electric field effect in atomically thin carbon films. Science. 2004. Vol. 306. Iss. 5696. P. 666—669.

31. Novoselov K.S., Falko V.I., Colombo L. et al. A roadmap for graphene. Nature. 2012. Vol. 490. Iss. 7419. P. 192—200.

32. Naguib M., Kurtoglu M., Presser V. et al. Two-dimensional nanocrystals produced by exfoliation of Ti3AlC2. Adv. Mater. 2011. Vol. 23. Iss. 37. P. 4248—4253.

33. Naguib M., Gogotsi Y. Synthesis of two-dimensional materials by selective extraction. Acc. Chem. Res. 2015. Vol. 48. Iss. 1. P. 128—135.

34. Gogotsi Y. Not just graphene: the wonderful world of carbon and related nanomaterials. MRS Bull. Vol. 40. Iss. 12. P. 1110—1120.

35. Lipatov A., Lu H., Alhabed M. et al. Elastic properties of 2D Ti3C2Tx MXene monolayers and bilayers. Sci. Adv. 2018. Vol. 4. Iss. 6. No. eaat0491.

36. Khazaei M., Arai M., Sasaki T. et al. Novel electronic and magnetic properties of two-dimensional transition metal carbides and nitrides. Adv. Funct. Mater. 2013. Vol. 23. Iss. 17. P. 2185—2192.

37. Zych Ł., Rutkowski P., Stobierski L. et al. The manufacturing and properties of a nano-laminate derived from graphene powder. Carbon. 2015. Vol. 95. P. 809—817.

38. Shabalin I.L. Nanotechnological advances in the hetero-structural materials design of ceramics. In: Proc. 5th Int. conf. «HighMatTech» (5—8 Oct. 2015). Kiev: National Academy of Science of Ukraine, 2015. P. 33—34.