Ceramic Nanomaterials Based on the Barium and Titanium Compounds, Prepared by the Sol - Gel Method, for Elecrotechnical Applications

Journal title

Archives of Metallurgy and Materials




No 4 December

Publication authors

Divisions of PAS

Nauki Techniczne


Institute of Metallurgy and Materials Science of Polish Academy of Sciences ; Commitee on Metallurgy of Polish Academy of Sciences




ISSN 1733-3490


Kogut K. (2009), Factors affecting the mechanism of flashover in metal oxide surge arrester, Archives of Metallurgy and Materials, 54, 4, 1013. ; K. Kogut, K. Kasprzyk, B. Zboromirska-Wnukiewicz, The materials with high electrical permittivity available to the capacitive constructions, PhD Workshop, Lublin 2010, "Prace Instytutu Elektrotechniki", Paper 248, 161-174 (2010). ; K. Kogut, B. Zboromirska-Wnukiewicz, K. Kasprzyk, T. Ruziewicz, K. Gryzła, R. Kłoś, The method of nanolayers preparing with high electrical permittivity, based on the barium and titanium compounds, with the use of the sol-gel method, for electrotechnical application. Phase 2., Electrotechnical Institute Technical Documentation No 500-9320-26, 2010. ; Viswanath R. (1997), Preparation and ferroelectric phase transition studies of nanocrystalline BaTiO3, Nanostructured Materials, 8, 2, 155, ; Salvatore Bruno (1993), High performance Multilayer Capacitor Dielectrics from Chemically Prepared Powders, Journal American Ceramics Society, 76, 5, 1233, ; Hasenkox U. (1998), Influence of precursor chemistry on the formation of MTiO3 (M=Ba, Sr) ceramics thin films, Journal of Sol-Gel Science and Technology, 12, 67, ; Thomas R. (1999), Electrical Properties of Sol-Gel Processed Amorphous BaTiO3 Thin Films, Journal of Sol-Gel Science and Technology, 16, 101, ; K. Gomi, K. Tanaka, H. Kamiya, Effect of Miting Conditio on Sol-Gel Synthesis of Bariom Titante ultrafine Particles, KONA No. 22, 177-185 (2004). ; Balachandran R. (2006), Particle Size Analysis of Barium Titanate Powder by Slow - Rate Sol-Gel Process Route, null, 406. ; Hsiao-Lin, Wang, Structure and dielectric properties of Perovskite - Barium Titanate (BaTiO3), Submitted in Partial Fulfillment of Course Requirement for MatE 115, Fall 2002, San Jose State University. ; Harizanov O. (2004), Formation and characterization of sol-gel barium titanate, Material Science and Engineering B, 106, 191, ; Makino T. (2007), Crystallinity of barium titanate nanoparticles synthesized by sol-gel method, Key Engineering Materials, 350, 31, ; <a target="_blank" href=''></a> ; Jurczyk M. (2004), Ceramic Nanomaterials. ; Veith M. (2000), Sol-Gel Synthesis of Nano-Scaled Ba-TiO3 and BaTi0,5Zr0,5O3 Oxides via Single - Source Alkoxide Precursors and Semi - Alkoxide Routes, Journal of Sol-Gel Science and Technology, 15, 145, ; Woo-Seok Cho (1998), Structural evolution and characterization of BaTiO3 nanoparticles synthesized from polymeric precursor, J. Phys. Chem. Solids, 59, 5, 659, ; Spin Coating Process Theory Description - <a target="_blank" href=''></a> ; <a target="_blank" href='εgcsmfo/facilities/dip-coating.htm'>εgcsmfo/facilities/dip-coating.htm</a> ; Andrade H. (2009), Barium titanate thin films prepared by dip-coating process, null. ; Rosenberger J. (null), Crystallization behavior of barium titanate thin films, Eurogel, 91', 92, 343. ; <a target="_blank" href=',82szklo,czytelnia.html+defekty+przy+dip+coating&cd=4&hl=pl&ct=clnk&gl=pl'>,82szklo,czytelnia.html+defekty+przy+dip+coating&cd=4&hl=pl&ct=clnk&gl=pl</a> ; Epcos - General Technical Information. ; J. den Toonder (2003), Residual Stresses in Multilayer Ceramic Capacitors: Measurement and Computation, Journal of Electronic Packaging, Transaction f the ASME, 125, 503. ; Keyston J. (1959), Coefficient of thermal expansion of barium titanate, The review of scientific instruments, 30, 4, 246,