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Muhammad Jawwad Saif, Muhammad Asif, Muhammad Naveed, Khalid Mahmood Zia, Waheed -uz- Zaman, Muhammad Kaleem Khosa and Muhammad Asghar Jamal

. Imai, T., Naitoh, Y., Yamamoto, T. & Ohyanagi, M. (2006). Translucent Nano Mullite Based Composite Ceramic Fabricated by Spark Plasma Sintering. J. Cer. Soc. JPN 1325(114), 138–140. DOI: 10.2109/jcersj.114.138. 5. Wilson, I.R. (2004). Kaolin and halloysite deposits of China. Clay Miner. 1(39), 1–15. DOI: 10.1180/0009855043910116. 6. Guo, B., Zou, Q., Lei, Y. & Jia, D. (2009). Structure and Performance of Polyamide 6/Halloysite Nanotubes Nanocomposites. Polym. J. 10(41), 835–842. 7. Handge, U.A., Hedicke-Höchstötter, K. & Altstädt, V. (2010

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P. Łada, A. Miazga, P. Bazarnik and K. Konopka

. Isono, Y. Shimamura, Fabrication of PSZ-Ti composites by spark plasma sintering and their mechanical properties, Mate.r Sci. Eng. A 621 , 166-172 (2015). [5] T. Yoshida, T. Hoshima, I. Mkaizawa, S. Sakurada, Properties of partially stabilized zirconia fuel cell, J. Electrochem. Soc. 136 (1989). [6] M.A. Borik, V.T. Bublik, A.V. Kulebyakin, E.E. Lomonova, F.O. Milovich, V.A. Myzina, V.V. Osiko, N.Y. Tabachkova, Phase composition, structure and mechanical properties of PSZ (partially stabilized zirconia) crystals as a function of stabilizing impurity

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Agata Dudek and Barbara Lisiecka

]. Lipinski, T. (2015). Morphology of Impurities in Steel after Desulfurization and Vacuum Degassing, 14th International Scientific Conference: Engineering For Rural Development, pp. 795-800. Marnier, G., Keller, C., Noudem, J. and Hug, E. (2014). Functional properties of a spark plasma sintered ultrafine-grained 316L steel. Materials and Design, [online] Volume 63, pp. 663-640. Available at: https://www.sciencedirect.com/science/article/pii/S0261306914005020 [Accessed 2 Jul. 2014]. Moteshakker, A. and Danaee, I. (2016). Microstructure and

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P. Kwaśniewski, G. Kiesiewicz, T. Knych, A. Mamala, M. Gniełczyk, A. Kawecki, B. Smyrak, W. Ściężor and E. Smaga-Sieja

/Cu, composites by spark plasma sintering, and their hardness and friction properties, Carbon, doi:10.1016 [4] T.S. Koltsova, L.I. Nasibulina, I.V. Anoshkin, V.V. Mishin1, E.I. Kauppinen, O.V. Tolochko and A.G. Nasibulin, New Hybrid Copper Composite Materials Based on Carbon Nanostructures, Journal of Materials Science and Engineering, B 2 (4), (2012). [5] D. Geng, B. Wu, Y. Guo, L. Huang, Y. Xue, J. Chen, G. Yu, L. Jiang, W. Hu, and Y. Liu, Uniform hexagonal graphene flakes and films grown on liquid copper surface, PNAS Early Edition, (2012). [6] Y. Jang, S

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M. Zygmunt-Kiper, L. Blaz and M. Sugamata

References [1] C. Suryanarayna, Mechanical alloying and milling, Progress in Materials Science 46, 1-184 (2001). [2] D.G. Ki m, J. Kaneko, M. Sugamata, Preferential oxidation of Mg in mechanically alloyed Al-Mg-Obased systems, Materials Transactions JIM 36, 305-311 (1995). [3] M. Kubota, P. Cizek, W.M. Rainfort h, Properties of mechanically milled and spark plasma sintered Al-15 at.% MgB 2 composite materials, Composites Science and Technology 68, 888-895 (2008). [4] K. Seimiya, M. Sugamata, L

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J. Dzik, A. Lisinska-Czekaj, A. Zarycka and D. Czekaj

magnetyczne ceramiki multiferroicznej Bi Fe O3, Prace Komisji Nauk Ceramicznych - Polski Biuletyn Ceramiczny Ceramika/Ceramics 101, 223-228 (2008). [4] J. Dzik, H. Bernard, K. Osinsk a, A. Lisins - ka- Czekaj, D. Czekaj, Synthesis, structure and dielectric properties of Bi1-x Ndx Fe O3, Archives of Metallurgy and Materials 56, 4, 1119-1125 (2011). [5] Z. Da i, Y. Akishige, Electrical properties of multiferroic Bi Fe O3 ceramics synthesized by spark plasma sintering, Journal of Physics D: Applied Physics 43, 445403-445407 (2010

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M. Chmielewski and W. Weglewski

J. Shusheng, “TiB2- AlN-Cu functionally graded materials (FGMs) fabricated by spark plasma sintering (SPS) method”, Key Engineering Materials 280-283, 1881-1884 (2005). [15] W. Weglewski, M. Basista, M. Chmielewski, and K. Pietrzak, “Modelling of thermally induced damage in the processing of Cr-Al2O3 composites”, Composites B 43 (2), 255-264 (2012). [16] M. Chmielewski, D. Kalinski, K. Pietrzak, and W. Wlosinski, “Relationship between mixing conditions and properties of sintered 20AlN/80Cu composite materials”, Archives of

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Ileana Nicoleta Popescu, Ruxandra Vidu and Vasile Bratu

. Titanium with aligned, elongated pores for orthopedic tissue engineering applications, In: Journal of Biomedical Materials Research Part A, 84A (2) (2008) 402-412. [43] Y. Zhao, M. Taya, Y. Kang, A. Kawasaki, Compression behavior of porous NiTi shape memory alloy, Acta Mater. 53 (2005) 337–343. [44] A. Dudek, M. Klimas, Composites based on titanium alloy Ti-6Al-4V with an addition of inert ceramics and bioactive ceramics for medical applications fabricated by spark plasma sintering (SPS method), In: Materialwissenschaft Und Werkstofftechnik, 46 (3) (2015) 237

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Tetiana Cherepova, Galyna Dmitrieva, Oleksandr Tisov, Oleksandr Dukhota and Myroslav Kindrachuk

on Ni/TiC composites by direct laser fabrication, Materials & Design , Vol. 30, Iss. 4. 1409–1412. 30. Zhang X.-H., Han J.-C., Du S.-Y., Wood J.V. (2000). Microstructure and mechanical properties of TiC-Ni functionally graded materials by simultaneous combustion synthesis and compaction, Journal of Materials Science , 35(8), 1925–1930. 31. Zohari S., Sadeghian Z., Lotfi B., Broeckmann C. (2015). Application of spark plasma sintering (SPS) for the fabrication of in situ Ni–TiC nanocomposite clad layer, Journal of Alloys and Compounds , 633, 479–483.

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Ilmārs Zālīte, Gundega Heidemane, Aija Krūmiņa, Dzintra Rašmane and Mikhail Maiorov

.11.167 [23] N. Millot, S. Le Gallet, D. Aymes, F. Bernard, and Y. Grin, “Spark plasma sintering of cobalt ferrite nanopowders prepared by coprecipitation and hydrothermal synthesis,” Journal of the European Ceramic Society , vol. 27, no. 2–3, pp. 921–926, Jan. 2007. https://doi.org/10.1016/j.jeurceramsoc.2006.04.141 [24] B. Xue, R. Liu, Z.-D. Xu, and Y.-F. Zheng, “Microwave Fabrication and Magnetic Property of Hierarchical Spherical α-Fe 2 O 3 Nanostructures,” Chemistry Letters , vol. 37, no. 10, pp. 1058–1059, Oct. 2008. https://doi.org/10.1246/cl.2008