Consolidation of commercially available titanium nitride nanostructured powder as well as nanocomposite powders in the Si3N4-TiN and TiN-TiB2 systems have been performed by Spark Plasma Sintering (SPS) in the temperature range from 1200°C to 1550°C. The effect of non-linear heating and loading regimes on high melting point nanocomposites consolidation has been investigated.
 M. Nygren, Z. Shen, On the preparation of bio-, nano- and structural ceramics and composites by spark plasma sintering Solid State Sciences 5, 125-131 (2003).
 J.R. Groza, A. Zavaliangos, Sintering activation by external electrical field, Mater. Sci. Eng. A287, 171-177 (2000).
 O. Zgalat- Lozynskyy, M. Herrmann, A. Ragulya, Spark plasma sintering of TiCN nanopowders in non-linear heating and loading regimes J. Europ. Ceram. Soc. 31, 809-813 (2011).
 V.G. Kolesnichenko, et al., Field assisted sintering of nanocrystalline titanium nitride powder Powder Metallurgy and Metal Ceramics, 157-166 (2010).
 O. Zgalat- Lozynskyy, M. Herrmann, A. Ragulya, Nanostructured composites based on high-melting nitrides Silicon Industries 147-152 (2004).
 O. Zgalat- Lozynskyy, M. Herrmann, A. Ragulya, Nanostructured composites in the TiN-Si3N4 system, Proc. of the 10th International Ceramics Congress (CIMTEC 2002), Part C- / Ed. P. Vincenzini. Techna Srl., 549-557 Faenza (2003).
 G. Bernard - Granger, et al., Spark plasma sintering ofacommercially available granulated zirconia powder-II. Microstructure after sintering and ionic conductivity / Acta Materialia 56, 4658-4672 (2008).
 D.A. Konstantinidis, E.C. Aifantis, On the anomalous hardness of nanocrystalline materials Nanostructured materials 7, 1111-1118 (1998).