Abstract
It is found that the formation of a titanium interlayer between a zirconium alloy doped with niobium (Zr–1% Nb) and a magnetron-sputtered titanium nitride coating by means of cathodic vacuum arc increases the adhesion strength of titanium nitride. Titanium nitride coatings have a NaCl-type cubic lattice and are mainly oriented parallel to the (100) plane. Upon thermal cycling in the temperature range of 20–800°C, the structure of the titanium interlayer transforms from α phase to β phase. Ti–TiN coatings are stable upon thermal cycling in the temperature range of 20–800°C. The deposition of a titanium interlayer does not increase the hydrogen permeability of titanium nitride.
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Original Russian Text © E.B. Kashkarov, N.N. Nikitenkov, M.S. Syrtanov, Yu.I. Tyurin, Zhang Le, 2015, published in Poverkhnost’. Rentgenovskie, Sinkhrotronnye i Neitronnye Issledovaniya, 2015, No. 12, pp. 74–77.
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Kashkarov, E.B., Nikitenkov, N.N., Syrtanov, M.S. et al. Formation of titanium interlayer by vacuum arc deposition to increase the durability of titanium nitride coatings under thermal cycling conditions. J. Surf. Investig. 9, 1277–1280 (2015). https://doi.org/10.1134/S1027451015060300
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DOI: https://doi.org/10.1134/S1027451015060300