X-RAY DIFFRACTION STUDIES OF COATINGS OF THE HAFNIUM-CARBON SYSTEM

The technology of co-precipitation of hafnium and carbon coatings with different concentrations of carbon has been developed. When performing research by the method of magnetron deposition, hafnium-carbon coatings are formed in the concentration range from 59.8 to 11.2 at. % Carbon. The study of the phase composition of the coatings obtained by the method of x-ray analysis. The phase composition of the coatings was determined depending on the concentration of carbon in hafnium.

1. Padture N. P., Gell M., and Jordan E. H., Thermal barrier coatings for gas-turbine engine applications // Science 296, 280 (2002).

2. Perepezko J. H., The hotter the engine, the better // Science 326, 1068 (2009).

3. Lu K., The future of metals // Science 328, 319 (2010).

4. Liu G., Zhang G. J., Jiang F., Ding X. D., Sun Y. J., Sun J., Ma E. Nanostructured high-strength molybdenum alloys with unprecedented tensile ductility // Nat. Mater. 12, 344 (2013).

5. Wuchina E., Opila E., Opeka M., Fahrenholtz W., Talmy I. UHTCs: Ultra-high temperature ceramic materials for extreme environment applications // Electrochem. Soc. Interface 16, 30 (2007).

6. Hong Q.-J. Prediction of the material with highest known melting point from ab initio molecular dynamics calculations // Physical Review B 92, 020104(R) (2015).

7. Marino K. A., Hinnemann B. Carter E. A. Atomic-scale insight and design principles for turbine engine thermal barrier coatings from theory // Proceedings of the National Academy of Sciences of the United States of America (PNAS), April 5, 2011, vol. 108, №.14, Р. 5480–5487.

8. Padture N.P, Gell M, Jordan E.H. Thermal barrier coatings for gas-turbine engine applications. // Science (2002) 296: 280–284.

9. Nieto A., Kuma A., Lahiri D., Zhang Ch., Seal S., Agarwal A. Oxidation behavior of graphene nanoplatelet reinforced tantalum carbide composites in high temperature plasma flow // Carbon, 67 (2014), 398–408.