[1] A. Knaislová, P. Novák, J. Linhart, I. Szurman, K. Skotnicová, J. Juřica, and T. Čegan, "Structure and Properties of Cast Ti-Al-Si Alloys," Materials (Basel), vol. 14, p. 813, 2021.
[2] J. Dai, J. Zhu, C. Chen, and F. Weng, "High temperature oxidation behavior and research status of modifications on improving high temperature oxidation resistance of titanium alloys and titanium aluminides: A review," Journal of Alloys and Compounds, vol. 685, pp. 784-798, 2016.
[3] R. Tewari, N. KSarkar, D. Harish, B. Vishwanadh, and G. K. Dey, Chapter 9-Intermetallics and Alloys for High Temperature Applications In Materials under Extreme Conditions. Amsterdam, The Netherlands: Elsevier, 2017.
[4] H. Clemens and S. Mayer, "Intermetallic titanium aluminides in aerospace applications – processing, microstructure and properties," Materials at High Temperatures, vol. 33, pp. 560-570, 2016.
[5] N. Cinca, C. R. C. Lima, and J. M. Guilemany, "An overview of intermetallics research and application: Status of thermal spray coatings," Journal of Materials Research and Technology, vol. 2, pp. 75-86, 2013.
[6] Y. Shida and H. Anada, "The influence of ternary element addition on the oxidation behaviour of TiAl intermetallic compound in high temperature air," Corrosion Science, vol. 35, pp. 945-953. 1993.
[7] A. Knaislová, P. Novák, M. Cabibbo, L. Jaworska, and D. Vojtěch, "Development of TiAl–Si Alloys—A Review," Materials, vol. 14, p. 1030, 2021.
[8] H.-P. Xiong, W. Mao, Y.-H. Xie, Y.-Y. Cheng, and X.-H. Li, "Formation of silicide coatings on the surface of a TiAl-based alloy and improvement in oxidation resistance," Materials Science and Engineering: A, vol. 391, pp. 10-18, 2005.
[9] T. C. Munro and B. Gleeson, "The deposition of aluminide and silicide coatings on γ-TiAl using the halide-activated pack cementation method," Metallurgical and Materials Transactions A, vol. 27, pp. 3761-3772, 1996.
[10] Y. Qiao, Z. Shen, and X. Guo, "Co-deposition of Si and B to form oxidation-resistant coatings on an Nb-Ti-Si based ultrahigh temperature alloy by pack cementation technique," Corrosion Science, vol. 93, 2015.
[11] W. Liang, X. X. Ma, X. G. Zhao, F. Zhang, J. Y. Shi, and J. Zhang, "Oxidation kinetics of the pack siliconized TiAl-based alloy and microstructure evolution of the coating," Intermetallics, vol. 15, pp. 1-8, 2007.
[12] J. Sun, Q. Fu, and L. Guo, "Influence of siliconizing on the oxidation behavior of plasma sprayed MoSi2 coating for niobium based alloy," Intermetallics, vol. 72, pp. 9-16, 2016.
[13] S. Teng, W. Liang, Z. Li, and X. Ma, "Improvement of high-temperature oxidation resistance of TiAl-based alloy by sol–gel method," Journal of Alloys and Compounds, vol. 464, pp. 452-456, 2008.
[14] D. Vojtěch, P. Novák, P. Macháč, M. Morťaniková, and K. Jurek, "Surface protection of titanium by Ti5Si3 silicide layer prepared by combination of vapour phase siliconizing and heat treatment," Journal of Alloys and Compounds, vol. 464, pp. 179-184, 2008.
[15] L. Zemˇcík, A. Dlouhý, S. Król, and M. Pra˙zmowskic, "Vacuum Metallurgy of TiAl Intermetallics," presented at the 14th International Conference on Metallurgy and Materials, Hradec nad Moravicí, Czech Republic, 24-26 May 2005., 2005.
[16] B. Bewlay, S. Nag, A. Suzuki, and M. Weimer, "TiAl alloys in commercial aircraft engines," Materials at High Temperatures, vol. 33, pp. 1-11, 2016.
[17] H.-P. Xiong, W. Mao, W.-L. Ma, Y.-H. Xie, Y.-F. Chen, H. Yuan, and X.-H. Li, "Liquid-phase aluminizing and siliconizing at the surface of a Ti60 alloy and improvement in oxidation resistance," Materials Science and Engineering: A, vol. 433, pp. 108-113, 2006
[18] S. Gray, M. H. Jacobs, C. B. Ponton, W. Voice, and H. E. Evans, "A method of heat-treatment of near γ-TiAl to enhance oxidation resistance by the formation of a Ti5Si3 layer," Materials Science and Engineering: A, vol. 384, pp. 77-82, 2004.
[19] P. Novák, J. Kříž, F. Průša, J. Kubásek, I. Marek, A. Michalcová, M. Voděrová, and D. Vojtěch, "Structure and properties of Ti–Al–Si-X alloys produced by SHS method," Intermetallics, vol. 39, pp. 11-19, 2013.
[20] Z. Q. Guan, T. Pfullmann, M. Oehring, and R. Bormann, "Phase formation during ball milling and subsequent thermal decomposition of Ti–Al–Si powder blends," Journal of Alloys and Compounds, vol. 252, pp. 245-251, 1997.
[21] P. Novak, D. Vojtěch, J. Šerák, J. Kubásek, F. Průša, V. Knotek, A. Michalcova, and M. Novák, "Synthesis of Intermediary Phases in Ti-Al-Si System by Reactive Sintering," Chemicke Listy, vol. 103, pp. 1022-1026, 2009.
[22] H. Aghajani, A. T. Tabrizi, S. A. Javadi, M. E. T. Tabrizi, A. Homayouni, and S. Behrangi, "Thermodynamically study of phase formation of Ni-Ti-Si nanocomposites produced by self-propagating high-temperature synthesis method," Synthesis and sintering, vol. 1, pp. 189-196, 2021.
[23] N. Sadeghi, H. Aghajani, and M. R. Akbarpour, "Microstructure and tribological properties of in-situ TiC-C/Cu nanocomposites synthesized using different carbon sources (graphite, carbon nanotube and graphene) in the Cu-Ti-C system," Ceramics International, vol. 44, pp. 22059-22067, 2018.
[24] Y. A. Sorkhe, H. Aghajani, and A. Taghizadeh Tabrizi, "Mechanical alloying and sintering of nanostructured TiO2 reinforced copper composite and its characterization," Materials & Design, vol. 58, pp. 168-174, 2014
[25] R. Khoshhal, M. Soltanieh, and M. Mirjalili, "Formation and Growth of Titanium Aluminide Layer at the Surface of Titanium Sheets Immersed in Molten Aluminum," Iranian Journal of Materials Science and Engineering, 2010.
[26] A. Školáková, P. Salvetr, J. Leitner, T. Lovaši, and P. Novák, "Formation of Phases in Reactively Sintered TiAl3 Alloy," Molecules, vol. 25, p. 1912, 2020
[27] A. Kamali, H. Razavizadeh, and M. Hadavi, "A process for production of titanium aluminide: Reaction mechanism," International Journal of Self-Propagating High-Temperature Synthesis, vol. 16, pp. 119-124, 2007.
[28] B. Liu and Y. Liu, "27 - Powder metallurgy titanium aluminide alloys," in Titanium Powder Metallurgy, M. Qian and F. H. Froes, Eds., ed Boston: Butterworth-Heinemann, pp. 515-531, 2015.
[29] V. V. Kurbatkina, "Titanium Aluminides," Concise Encyclopedia of Self-Propagating High-Temperature Synthesis, pp. 392-393, 2017.
[30] H. Hyer, L. Zhou, A. Mehta, S. Park, T. Huynh, S. Song, Y. Bai, K. Cho, B. McWilliams, and Y. Sohn, "Composition-Dependent Solidification Cracking of Aluminum-Silicon Alloys During Laser Powder Bed Fusion," Acta Materialia, vol. 208, p. 116698, 2021.
[31] H.-W. Liu and K. P. Plucknett, "Titanium aluminide (Ti-48Al) powder synthesis, size refinement and sintering," Advanced Powder Technology, vol. 28, pp. 314-323, 2017.
[32] R. Khoshhal, M. Soltanieh, and s. Boutorabi, "Investigation on the reactions sequence between synthesized ilmenite and aluminum," Journal of Alloys and Compounds, vol. 628, pp. 113-120, 2015.
[33] A. P. Woodfield, P. J. Postans, M. H. Loretto, and R. E. Smallman, "The effect of long-term high temperature exposure on the structure and properties of the titanium alloy Ti 5331S," Acta Metallurgica, vol. 36, pp. 507-515, 1988.
[34] D. Vojtěch, H. Čížová, K. Jurek, and J. Maixner, "Influence of silicon on high-temperature cyclic oxidation behaviour of titanium," Journal of Alloys and Compounds, vol. 394, pp. 240-249, 2005.
[35] D. Vojtěch, B. Bártová, and T. Kubatı́k, "High temperature oxidation of titanium–silicon alloys," Materials Science and Engineering: A, vol. 361, pp. 50-57, 2003
[36] L. J. Brillson, M. L. Slade, and H. W. Richter, "Titanium–silicon and silicon dioxide reactions controlled by low temperature rapid thermal annealing," Journal of Vacuum Science & Technology A, vol. 4, p. 993, 1986.
[37] I. J. M. M. Raaijmakers, "Fundamental aspects of reactions in titanium-silicon thin films for integrated circuits," Phd Thesis, Technische Universiteit Eindhoven, Research TU/e / Graduation TU/e, 1988.
[38] K. Maex, R. F. d. Keersmaecker, M. v. Rossum, W. F. v. d. Weg, and P. G. Krooshof, "Metals and Silicides," presented at the Workshop on Refr. , Aussois (France), 1987.
)
ارسال نظر در مورد این مقاله