[1] Kollenberg,W., Schneider H., Microhardness of Mullite at Temperatures to 1000, J. Am. Ceram. Soc., 72, p. 1739 (1989).
[2] Hynes A.P., Doremus R.H., High-Temperature Compressive Creep of Polycrystalline Mullite, J. Am. Ceram Soc., 74, p. 2469 (1991).
[3] Aksay A., Dabbs D.M., Sarikaya M., Mullite for Structural, Electronic, and Optical Applications, J. Am. Ceram. Soc., 74, p. 2343 (1991).
[4] Schneider H., Eberhard E.,Thermal Expansion of Mullite, J Am. Ceram. Soc., 73, p. 2073 (1990).
[5] Kanka B., Schneider H., Sintering Mechanisms and Micro-Structural Development of Co-Precipitated Mullite, J. Mater. Sci., 29, p. 1239 (1994).
[6] Sarikaya M., Aksay, I.A., Spinel Phase Formation During the 980 °C Exothermic Reaction in the Kaolinite-to-Mullite Reaction Series, J. Am. Ceram. Soc., 70, p. 837 (1987).
[7] Cameron W.E., Mullite: a substituted Alumina, Am. Miner., 62, p. 747 (1977).
[8] Somiya S., Hirata Y., Mullite Powder Technology and Applications in Japan, Ceram. Bull, 70, p. 1624 (1991).
[9] DavisR.F., Pask J.A., in : Alper A.M., ed., "High Temperature Oxides", Academic Press,New York, p. 37 (1971).
[10] Hench L.L., Vasconcelos W.L., Sol-Gel Process Using Aluminum Oxychloride, Aluminosilicate and Aluminum Borosilicate, Annu. Rev. Mater. Sci., 20, p. 269 (1990).
[11] Hench L.L., West J.K., The Sol-Gel Process, Chem. Rev., 90, p. 33 (1990).
[12] Komarneni S., Some Significant Advances in Sol-Gel Processing of Dense Structural Ceramics,
J. Sol-Gel Sci. Tech. 6, p. 127 (1996).
[13] Schneider H., Saruhan B., Voll D., Merwin L., Mullite Precursor Phases, J. Eur. Ceram. Soc., 11, p. 87 (1993).
[14] Hoffman D.W., Roy R., Komareni S., Diphasic Xerogels, A New Class of Materials: Phases in the System Al2O3-SiO2, J. Am. Ceram. Soc., 67, p. 468 (1984).
[15] Chakravorthy A.K., Ghosh D.K.,Kaolinite-Mullite Reaction Series: The Development and Significance of a Binary Aluminosilicate Phase, J. Am. Ceram. Soc., 74, p. 2359 (1991).
[16] Schneider H., Voll D., Sahuran B., Sanz J., Schrader G., Ruscher C., Mosset A., Synthesis and Structural Characterization of Non-Crystalline Mullite Precursors, J. Non-Cryst. Soid, 178, p. 262 (1994)
[17] JaymersI., Douy A., Homogeneous Precipitation of Mullite Precursors, J. Sol-Gel Sci. Tech, 4, p.7 (1995).
[18] Pach L., Iratni A., Hrabe Z., Svetik S., Komarneni S.S., Sintering and Crystallization of Mullite in Diphasic Gels, J. Mater. Sci., 30, p. 5490 (1995).
[19] Heinrich T., Raether E., Marsmann H., Growth and Structure of Single Phase Mullite Gles from Chelated Aluminum Alkoxides and Alkoxysilanes, J. Non-Cryst. Solid, 168, p.14 (1994).
[20] Epicier T., Benefits of High-Resolution Electron Microscopy for Structural Characterization of Mullites, J. Am Ceram. Soc., 74, p. 2359 (1991).
[21] Kuper G., Peitz B., WinterI., Hormes J., Schneider H., Schumeker M., Voll D., Aluminum K-Edge Absorption (XANES) Studies of Noncrystalline Mullite Precursors, J. Am. Ceram. Soc., 81, p. 813 (1996).
[22] Jaymes I., Douy A., Massiot D., Counters J.P., Characterization of Mono- and Diphasic Mullite Precursor Powders Prepared by Aqueous Routes. 27Al and 29Si MAS-NMR Spectroscopy Investigations, J. Mater Sci., 31, p. 4581 (1996).
[23] Schneider H., Merwin L., Sebald A., Mullite Formation from Non-Crystalline Precursors, J. Mater. Sci., 27, p. 805 (1992).
[24] Kansal P., Laine R.M., Babonnean F., A Processable Mullite Precursor Prepared by Reacting Silica and Aluminum Hydroxide with Triethanolamine in Ethylene Glycol: Structural Evolution on Pyrolysis, J. Am. Ceram. Soc., 80, p. 2597 (1997).
[25] Li D.X., Thomson W.J., Mullite Formation from Nonstoichiometric Diphasic Precursors, J. Am. Ceram. Soc., 73, p. 9641 (1990).
[26] Ruscher C.H., Schrader G., Gotte M., Infra-red Spectroscopic Investigation in the Mullite Field of Composition: Al2(Al2+2xSi2-2x)O10-x with 0.55>x>0.25, J. Eur. Ceram. Soc., 161, p. 69 (1996).
[27] Janackovic D.J., Jakanovic V., Kostic-Gvozdenovic L.J., Uskokovic D., Modeling of Nanostructural Design Using Ultrasonic Spray Pyrolysis, Nanostruc. Mater., 10, p. 341, (1998).
[28] Okada K., Otsuka N., Characterization of the Spinel Phase from SiO2-Al2O3 Xerogels and the Formation Process of Mullite, J. Am. Ceram. Soc., 69, p. 652 (1986).
[29] Orefice B.L., Vasconcelos W.L., Sol-Gel Transition and Structural Evolution on Multicomponent Gels Derived from the Alumina-Silica System, J. Sol-Gel Sci Tech., 9, p. 239 (1977).
[30] Bertoluzaa A., Fagnano C., Moreli M.A., Gottardi V., Raman and Infraded Spectra on Silica Gel Evolving Toward Glass, Guglielni M.J., J. Non-Cryst, Solids, 53, p. 279 (1982).