PSI - Issue 50

N.F. Morozov et al. / Procedia Structural Integrity 50 (2023) 192–199 Author name / Structural Integrity Procedia 00 (2019) 000 – 000

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As it has been shown, the reinforcing phases of various structures have different effects on the mechanical properties of the Al matrix composite. Reinforcement of an Al matrix composite with 0.1% CNT does not significantly increase the strength of the composite and maintain plasticity at the level of Al material. At the same time, the TiC phase with a dispersion of 150 nm significantly reduces the plasticity of the composite, but significantly increases its strength. From the point of view of the authors of the article, the joint use of two reinforcing phases (CNT and nanoscale carbide particles) would allow to obtain a composite material with higher strength characteristics with the preserved plasticity of the composite. Funding The research was conducted under the financial support the Russian Science Foundation grant (project No. 20 11-20083). Acknowledgements The research was carried out using the equipment of the resource centers of the St. Petersburg State University Scientific Park "X-ray Diffraction research methods" and "Nanotechnology". References Hansang, K., Dae, H., Jean, F., Akira, K., 2010. Investigation of Carbon Nanotube Reinforced Aluminum Matrix Composite Materials. Composites Science and Technology 70, 546 – 550. Bakshi, S., Agarwal, A., 2011. An Analysis of the Factors Affecting Strengthening in Carbon Nanotube Reinforced Aluminum Composites. Carbon 49, 533 – 544. Choi, H., Shin, J., Bae, D., 2011. Grain Size Effect on the Strengthening Behavior of Aluminum-Based Composites Containing Multi-Walled Carbon Nanotubes. Composites Science and Technology 71, 1699 – 1705. Jin-zhi, L., Ming-Jen, T., Idapalapati, S., 2010. Spark Plasma Sintered Multi-Wall Carbon Nanotube Reinforced Aluminum Matrix Composites. Materials & Design 31, 96 – 100. Singhal, S., Renu, P., Mamta, J., Rajiv, C., Satish, T., Mathur, R., 2012. Carbon Nanotubes: Amino Functionalization and Its Application in the Fabrication of Al-matrix Composites. Powder Technology 215 – 216, 254-263. Salas, W., Alba-baena, N., Murr, L., 2007. Explosive Shock-Wave Consolidation of Aluminium Powder. Carbon Nanotube Aggregate Mixtures: Optical and Electron Metallography. Metallurgical and Materials Transactions A 38, 2928 – 2935. Deng, C., Wang, D., Zhang, X., Ma, Y., 2007. Damping Characteristics of Carbon Nanotube Reinforced Aluminum Composite. Materials Letters 61, 3229 – 3231. Jafari, M., Abbasi, M., Enayati, M., Karimzadeh, F., 2012. Mechanical Properties of Nanostructured Al2024 – MWCNT Composite Prepared by Optimized Mechanical Milling and Hot Pressing Methods. Advanced Powder Technology 23, 205 – 210. Esawi, A., El Borady, M., 2008. Carbon Nanotube-Reinforced Aluminium Strips. Composites Science and Technology 68, 486 – 492. Morsi, K., Esawi, K., Borah, P., Lanka, S., Sayed, A., Taher, M., 2010. Properties of Single and Dual Matrix Aluminum – Carbon Nanotube Composites Processed via Spark Plasma Extrusion (SPE). Materials Science and Engineering 527, 5686 – 5690. Alekseev, A., Predtechenskiy, M., 2016. Aluminum foil reinforced with carbon nanotubes. Nanosystems: Physics, Chemistry, Mathematics 7, 185 – 189. Yufeng, W., Gap-Yong, K., 2011. Carbon Nanotube Reinforced Aluminum Composite Fabricated by Semi-Solid Powder Processing. Journal of Materials Processing Technology 211, 1341-1347. Kang, Y., Cao, M., Shi, X., Hou, Z., 2007. The enhanced dielectric from basalt fibers/nickel core-shell structures synthesized by electroless plating. Surface and Coatings Technology 201, 7201 – 7206. Zemtsova, E., Yurchuk, D., Morozov, P., Kudymov, V., Smirnov, V., 2021. Features of the synthesis of the dispersed tic phase with nickel nanostructures on the surface to create an aluminum-based metal composite. Nanomaterials 11, 2499. Tolochko, O., Koltsova, T., Bobrynina, E., Rudskoy, A., Zemtsova, E., Kirichenko, S., Smirnov, V., 2019. Conditions for production of composite material based on aluminum and carbon nanofibers and its physic-mechanical properties. Nanomaterials 9, 550.

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