Nanoscience, Vol. 1, Issue 1, Sep  2018, Pages 40-66; DOI: 10.31058/j.nano.2018.11004 10.31058/j.nano.2018.11004

Nanoceramics: Materials, Properties, Methods and Applications-Part II

Nanoscience, Vol. 1, Issue 1, Sep  2018, Pages 40-66.

DOI: 10.31058/j.nano.2018.11004

Hassan Hassanien Mohamed Darweesh 1*

1 Refractories, Ceramics and Building Materials Department, National Research Center, Dokki, Cairo, Egypt

Received: 26 December 2017; Accepted: 20 January 2018; Published: 9 March 2018

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Abstract

The overwhelming interest of nanotechnology including nanoparticles, nanocrystals, nanostructure and nanoscales of all ceramic materials especially nanoceramics is one of the most exciting fields so that it incorporates materials sciences, cement, concrete and other building materials particularly bricks, ceramic wall and floor tiles and also advanced bioceramics industries. In this review article, the author wishes to indicate the importance of nanomaterials and/or nanoparticles for improving the physicochemical and mechanical properties, thermal shock, thermal expansion, firing resistance and microstructures of the resulting nanoceramic products.

Keywords

Nanoceramics, Materials, Properties, Methods, Application

Copyright

© 2017 by the authors. Licensee International Technology and Science Press Limited. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

References

[1] Abdel-Razek Khalil, A., (2012). Advanced Sintering of Nano-Ceramic Materials. Ceramic Materials - Progress in Modern Ceramics.
[2] Fesenmaier, K. Ceramics Dont Have To Be Brittle. CalTech. Retrieved 11 September 2014.
[3] Fesenmaier, K. Made-to-Order Materials. Caltech. Retrieved 5 September 2013.
[4] Nissan, B., (2014). Nanoceramics in Biomedical Applications. MRS Bulletin 29 (1): 28–32.
[5] Singer, F. and Singer, S.S., “Industrial Ceramics”, 2nd Edn. Leipziger, Druchkaus, GDR, 1971.
[6] ASTM- Specification, C326-32-76, 1980 “Standard Test Method for shrinkage of ceramic white ware clays after drying and firing”, Part, 17: 266-267.
[7] Rayan, R.W. and Radford, C., “White wares production, testing and quality control”, 1st Edn. The Institute of Ceramics, Pergamon Press. Oxford, New York, Beijing, Sedney, Frankfurt, Sao Paulo, Tokyo, Toronto, 1987.
[8] Drews, M., “Wall and floor tiles”, Ceramic Monographs 2.4.1. Verlag Schmid GmbH, 1983.
[9] Rayan, R.W., “Properties of ceramic raw materials”, 2nd Edn. Pergamon Press, 1978.
[10] K. Sobolev, K. and Ferrada-Gutiérrez, M., “How nanotechnology can change the concrete”, world: Part 1, Am Ceram Soc Bull, 84 (10) (2005), pp. 14–17.
[11] Schulle, K.H., “Reactions between Mullite and glassy phase in Porcelains”, Trans. Brit Ceram.Soc. , 63, 103, 1964.
[12] Kisel, I.I., Strodyreva, G.V. and Demidovisch, V.B., “Possibilities of using local clay in manufacturing floor tiles”, Steklo, Sitally Silik, 1980.
[13] Danto Co. Ltd. “Decorative tiles”, Jpn. Kokai, 79/70, 250, Jan. 14, 1979.
[14] Vauequelin, M.; Gault, C. and Boch, B., “Reheology of clay mixture ceramic bodies”, Ind. Ceram. 744, 736-740, 1980.
[15] Fiori, C. and Fabbri, B., “Granite containing bodies for the production of Stoneware tiles”, Res. Inst. Ceram. Techn. National Res. Council, Faenza, Italy, InterCeram 32, 1, 21-22, 1983.
[16] Darweesh, H.H.M. “Utilization of Cement Kiln Dust in Ceramics to minimize Environmental Pollution”, M. Sc. Thesis, Inst. Environmental Studies and Researches, Ain Shams Univ. Oct. 1992.
[17] Mostafa, M,Z. and Darweesh, H.H.M., “Preparation of ceramic floor tiles containing local waste of cement kiln dust”, The 8th SIMCER Intern. Symposium on “Ceramics”, RIMINI (Italy)-Exhibition Centre, Nov. 10-12, 1992.
[18] Todor, D.N., “Thermal analysis of minerals”, English Edn., Abacus Press, 1972.
[19] Mostafa, M.Z. and Darweesh, H.H.M., “Mechanical properties of ceramic floor tiles containing local waste of cement kiln dust”, The 8th SIMCER Intern. Symposium on Ceramics, Rimini (Italy)-Exhibition Centre, Nov. 10-12, 1992.
[20] kingery, W.D.; Bowen,H.K. and Uhlmann, D.R., “Introduction to Ceramics”, 2nd edn., john Wiley and Sons, New York, London, Sydney, Toronto, 361, 594, 1975.
[21] Tseng, T.Y. and Nalwa, H.S. (eds.,) Handbook of Nanoceramics and Their Based Nanodevices, Volume 1-5, American Scientific Publishers, Los Angeles, CA (2009).
[22] G. Jackson “Introduction to white wares”, Elsevier Publishing Co., 1st Edn. 1969.
[23] Chiang, Y.M. Birnie, D.P. and Kingery, W.G., “Physical Ceramics - Principals for Ceramic Science and Engineering”, 3rd Edn., John Wiley and Sons, Lehigh Press. Inc., USA, 1997.
[24] Konta, J., “Properties of ceramic raw materials”, Ceramic Monograph 1.1.4. Verlag Schmid G.m.b.H., 1981.
[25] Grim, R.E. “Clay Mineralogy”McGraw Hill, NewYork, 1962.
[26] Schuller, K. H. and Jager, H., “The chemistry and properties of feldspar and their effects in porcelain” Ber. Dt. Keram. Ges., 56, 29, 1979.
[27] Kashlyak, L. L. and Kareev, Yu.B., “Production of tiles for floor and Façade tiles in the Leningrad Ceramic Products Plant”, Keram from St.8, 10, 1978.
[28] Darweesh, H.H.M. and El-Din, M. N., “Characterization of some Egyptian Granites and Marbles as dimensional stones” Bull. NRC, Egypt, 25, 4, 2000, 323-339.
[29] Bacanac, M. and Babic, M., “Materials for ceramic tiles with a backing temperature of 1080 Cand use of Trokyte”, Technika, Belgrade, 39, 4, 1984, 1-5.
[30] Belous, K. P.; Kushel, M.I.; Evplov, Yu.N. and Ohkrimenco, G.M., “Effects of technological factors on the strength of ceramic materials”, Inst. Probl. Prockn. , Kiev, USSR, 2, , 1989, 42-49.
[31] watchman, J. B., “Mechanical properties of ceramics-An introductory Survey”, Ceram Bull., 46, 1967, 756-762.
[32] Warshow, S. I. and Seider R., “Comparison of strength of triaxial porcelains containing alumina and silica”, J. Amer. Ceram; Soc., 50, 1967, 337-342.
[33] Genin, G., “Influence of Quartz on the strength of porcelain”, Stekelo. Keram., 15, 35, 1958.
[34] Kalnin, I. L. “Strength and elasticity of Whitewares-Part I; Relation between Flexural strength and elasticity”, Ceram. Bull., 46, 1174, 1967.
[35] Kalnin, I. L.; Cucka, P.; Warshow, S. I. and Seider, R. “Strength and elasticity of Whitewares”, Ceram. Bull., 47, 498, 1968.
[36] Mortel, H. “Porcelains for fast firing”, InterCeram, 3, 65, 1977.
[37] Giomlem, K. and Lyng, S. “Anorthosite as a ceramic raw material-Part II; Anorthosite for tile manufacture”, Trans. Brit. Ceram. Soc. 73, 139, 1974.
[38] Joachim, S.; Manfred, S. and Peter, T., “Ceramic composition for light-colored gehlinite-free glazed earthenware tiles”, VEB kombinat Fliesen and Sanitaerkeramic “Kurt Buerger”, Ger. (East), DD 205, 883, CI CO 4B33 /00, Jpn. Jan, 11, 1984.
[39] Budnikov, P. P., “The technology of Ceramics and Refractories”, Edward Arnold Publishers Ltd., London, 1964.
[40] El-Alfi, E. A.; Radwan, A. M. and Darweesh, H.H.M., (2004), “Effect of sand as non-plastic material on ceramic properties of clay bricks” InterCeram (Intern. Cer. Review), 53, 5, 330-333.
[41] H. H. M. Darweesh, H. M. Awad and A. Tawfik (2011) “Red Bricks from Dakhla Formation Clay - Tushka area-Incorporated with some Ind. Wastes or byproducts” Industrial Ceramics, Italy, Vol. 31, No. 3, 201-207.
[42] Darweesh, H. H. M. and El-Meligy, M. G., (2014) “Non-conventional light-weight Clay bricks from homra and kraft pulp wastes”, J. Chemistry and Materials Research Vol. 1, No. 4, 1-7.
[43] Aggarwal, P. S.; Lele, R. V. and Sen, S. K., “utilization of fly ash for making wall tiles”, Central Glass and Ceramic Res. Inst. Calcotta, 700 012 India, Cent. Glass Ceram. Res. Inst. Bull., 27 (1-2), 1980.
[44] Khrundzh, A. V. and Babushkin, V. I., “State Reginal electric power plant wastes used for the manufacture of ceramic tiles”, USSR, Steklo, Keram. 3, 1983, 6-8.
[45] Hou, P., Qian, J., Cheng, X., Shah and S. P. (2015). “Effects of the pozzolanic reactivity of nano SiO2 on cement-based materials”. Cem. Concr. Compos., vol. 55, 250-258. DOI: 10.1016/j.cemconcomp.2014.09.014.
[46] Keskinateş, M., Felekoğlu, K. T., Felekoğlu, B. and Gödek, E. (2016). “Çimento Esaslı Lifli Kompozitlerde Su/Çimento Oranı ve Mineral Katkı Türünün Çoklu Çatlak Davranışına Etkisi”. Deu Muhendis. Fak. Fen ve Muhendis., vol. 18, no. 54, pp. 440–440.
[47] Ibrahim, D. M. M.; Abdel-Fattah, W. I. and Nour, F., “Air-cooled blast furnace slag as a fluxing material in the Ceramic Industry”, Ber. Dt. Keram. Ges. 57, 9-10, 1980, 187-194.
[48] Pinalova, D.; kukushiva, M. and Belchev, K., “Wastes from Coal benefication for effective manufacture of ceramic products”, Stroit. Mater. Silik., 25, 6, 1984, 14-15.
[49] Anlagenbau, A., (1984), “Ceramic tiles”, GmbH, Ger. Offen. DE 3 313, 594 (CI. CO 4B33/34), Oct., 18, 1984. Chem. Abst. 102:49975 k, 1995.
[50] Saltyvskaya, I. M., (1984), “Use of chemical industry byproducts for the manufacture of ceramic tiles”, (Khar’k. Inzh.-Ekon. Inst. Khakov, USSR). Steklo Keram, 9, 19-20. Chem. Abst. 102: 30662j, 1985.
[51] Pitskhelauri, I. A.; Lomidze, N. M.; Chkheidze, K. S.; Sakandlidze, A. A. and Zambakhidze, N. P., (1987), “Raw mixtures for producing ceramic wall articles”, Tbilisi State Academy of Arts, USSR, Su 1, 357, 392 (C1./ CO 4B33/00), Dec. 7, 1987. Chem. Abst. 108: 100003v, 1988.
[52] Darweesh, H.H.M.; Wahsh, M.M.S. and Negim, E.M., (2012) “Densification and Thermomechanical Properties of Conventional Ceramic Composites Containing Two Different Industrial Byproducts”, Amer.-Eurasian Journal of Scientific Research, 7 (3), 123-130.
[53] Mukhamedzhanov, M.T.; Palvanov, V.P.; Irkahodzhaeva, V.P. and Toirova, M.Kh., (1990), “The use of mining tailings in the manufacture of ceramic tiles”, Inst. Sredazuiprotsvtmet, Almalyk, USSR, Kompleksen. Ispol’z. Miner.Syr’ya, 11, 82-84. Chem. Abst. 114: 212495n, 1991.
[54] Moroz, B.I.; Gumenyuk, A.E.; Mel’nekov, V.M. and Trubachov, V.I., (1990), “Bodies for the manufacture of ceramic tiles”, USSR, Stroit. Mater. Konstr., 2, 17. Chem. Abst. 114: 10710y, 1991.
[55] Keijiro, S.; Takashi, O.; Yoshifumi, K.; Yoshiyuki, O.; Masaru, T. and kozo, M., (1991) “Manufacture of ceramics containing Portland cement”, Sumitomo Cement Co. Lmt., Jpn. Kokai, Tokyo Koho JP, o3, 215, 350 [91, 215, 350](C1. CO 4B35/16). Chem. Abst. 115: 285800p, 1991.
[56] Abdel-Fattah, W.I. and Nour, F.A., “Utilization of electrostatic precipitator dust in borcelain”, XIII- Silicon, For silicate Industry and Science Conferences, Budapest, June, 1981.
[57] Abdel-Fattah, W.I.; El-Didamony, H. and Taha, A. S., “Synthesis and thermal characteristics of Ca rich phases”, TIZ-Fachberichte, 106, 5, 1982, 351-354.
[58] Abdel-Fattah, W. I. and El-Didamony, H.,”, Thermal investigation on electrostatic precipitator kiln dust”, Thermochimica, Acta, 51, 1981, 297-306.
[59] Darweesh, H.H.M., (2001) “Building materials from siliceous clay and low grade dolomite rocks”, Ceramics International, 27, 45-50.
[60] Sahmaran, M., Yildirim, G., Erdem, T. K. (2013), “Self-healing capability of cementitious composites incorporating different supplementary cementitious materials”. Cem. Concr. Compos., vol. 35, no. 1, pp. 89–101.
[61] Darweesh, H.H.M, (2001), “Utilization of Cement Kiln Dust Waste as a source of CaO in Ceramic Industry”, Sil. Industriels (Ceramic Science and Technology), 66, 3-4, 47-52.
[62] H. H. Darweesh, H.H.M. and Khalil, N.M., “Effect of cement bypass dust waste on the physico-mechanical properties of alumina cement” Ind. J. Chem. Techn. India, 7, 2001, 287-291.
[63] Madandoust, R., Mohseni, E., Mousavi, S. Y., Namnevis, M. (2015). An experimental investigation on the durability of self-compacting mortar containing nano-SiO2, nano-Fe2O3 and nano-CuO. Constr. Build. Mater., vol. 86, pp. 44–50.
[64] ASTM-Specification, C373-72, 1980 “Standard Test Method for water absorption, bulk density, apparent porosity and specific gravity of whiteware products”, Part, 17: 308-309.
[65] ASTM- Specification, C674-71, 1980 “Standard Test Method for flexural properties of ceramic white ware Products”, Part, 17: 668-671.
[66] Taha, R. T. A., (2011), “Bioceramic composites suitable for bone graft”, M. Sc. Thesis (Biophysics), University College of Women, Ain Shams University.
[67] Mohamed, E.M., (2012), “Inorganic –organic hybrids based on PVA and Silica with added titania”, M. Sc. Thesis (Biophysics), University College of Women, Ain Shams University.
[68] A. Akın1*, A. J. Zia, “Investigation of the Effect of Curing Applications Containing Different Nano Silica on the Strength of Cementitious Composites”, ISSN: 2587-0742, -ISSN: 2587-1749, 1(Special Issue), 2017, 47-51.