Self-propagating high-temperature synthesis of AlN–TiC powder composition using sodium azide and C2F4 fluoroplastic
- Authors: Belova G.S.1, Titova Y.V.1, Maidan D.A.1, Yakubova A.F.1
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Affiliations:
- Samara State Technical University
- Issue: No 3 (2024)
- Pages: 9-16
- Section: Articles
- URL: https://vektornaukitech.ru/jour/article/view/964
- DOI: https://doi.org/10.18323/2782-4039-2024-3-69-1
- ID: 964
Cite item
Abstract
Producing powder compositions using conventional processing technology can lead to the formation of large agglomerates and, therefore, makes it difficult to obtain a uniform microstructure. The production of composites by self-propagating high-temperature synthesis can reduce costs and the number of technological stages, as well as lead to obtaining composites that are more homogeneous. Synthesis by the combustion of mixtures of powder reagents of sodium azide (NaN3), fluoroplastic (C2F4), aluminum and titanium with different ratios of reagents in a nitrogen gas atmosphere at a pressure of 4 MPa was used for the production of a highly dispersed powder ceramic AlN–TiC composition. Thermodynamic calculations have confirmed the possibility of synthesis of AlN–TiC compositions of different formulations in combustion mode. The dependences of temperature and combustion rate on the composition of the initial mixtures of reagents were experimentally determined for all stoichiometric reaction equations. The study have shown that the experimentally found dependences of combustion parameters on the ratio of the initial components correspond to the theoretical results of thermodynamic calculations. The formulation of the synthesized composition differs from the theoretical composition by a lower content of target phases and the formation of Al2O3, Na3AlF6 and TiO2 side phases. The powder composition consists of aluminum nitride fibers with a diameter of 100–250 nm and ultradisperse particles of predominantly equiaxed and lamellar shapes with a particle size of 200–600 nm. As the combustion temperature increases to produce the largest amount of titanium carbide phase, the particle size increases to the micron level.
About the authors
Galina S. Belova
Samara State Technical University
Author for correspondence.
Email: galya.belova.94@mail.ru
ORCID iD: 0000-0002-6430-9408
PhD (Engineering), junior researcher of the Laboratory “Digital Twins of Materials and Technological Procedures of their Processing”
Russian Federation, 443100, Russia, Samara, Molodogvardeyskaya Street, 244Yulia V. Titova
Samara State Technical University
Email: titova600@mail.ru
ORCID iD: 0000-0001-6292-280X
PhD (Engineering), Associate Professor, assistant professor of Chair “Materials Science, Powder Metallurgy, Nanomaterials”
Russian Federation, 443100, Russia, Samara, Molodogvardeyskaya Street, 244Dmitry A. Maidan
Samara State Technical University
Email: mtm.samgtu@mail.ru
ORCID iD: 0000-0002-0195-4506
PhD (Engineering), Associate Professor, assistant professor of Chair “Materials Science, Powder Metallurgy, Nanomaterials”
Russian Federation, 443100, Russia, Samara, Molodogvardeyskaya Street, 244Alsu F. Yakubova
Samara State Technical University
Email: minekhanovaaf@mail.ru
ORCID iD: 0000-0002-6081-8264
postgraduate student
Russian Federation, 443100, Russia, Samara, Molodogvardeyskaya Street, 244References
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