Paper Titles
Foreword
Synthesis of Oxide Nanocomposite Particles by Reactive Spray Pyrolysis
p.3
Some Current Processing Issues in Barium Titanate Powders
p.9
Grain Morphology Memory: Yttria as a Study Case
p.15
Effects of Positive Ionic Radius on the Phase Transition of Titania Nano Powders from Aqueous TiOCl2 Solutions
p.21
Silicon Carbonitride Nanopowders by Laser Pyrolysis for Plastic Nanocomposites
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Reactivity of AlN Powder in an Aqueous Environment
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Solid-State Synthesis of Pb2Sr2CaCu3-ySx and Conducting Properties
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Synthesis and Reactions Behavior of Calcium Zirconate/Magnesium Oxide from Natural and Synthetic Raw Materials by Neutron Thermodiffractometry
p.37

Some Current Processing Issues in Barium Titanate Powders

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Key Engineering Materials (Volumes 264-268)

Pages:

9-14

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.264-268.9

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Online since:

May 2004

Authors:

B.I. Lee, Ming Xia Wang, D.H. Yoon

Keywords:

Barium Titanate Powder, Leaching, Nanoparticle, Passivation

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© 2004 Trans Tech Publications Ltd. All Rights Reserved

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References

[1] S.A. Constantino, Am. Ceram. Soc. Bull., 71, (1992) 787-8.

Google Scholar

[2] L. Mann, Vice President, Kemet Electronics Corp., Seminar given at Clemson Univ., Sept 26, (2002).

Google Scholar

[3] I. Henderson and R. Staut, Ceramic Industry, December 1996, p.30.

Google Scholar

[4] G.D. Parfitt, Dispersion of Powders in Liquids, 2nd ed., John Wiley Pub., New York, (1973).

Google Scholar

[5] R. E. Johnson, Jr. and W. H. Morrison, Jr., Ceramic Powder Dispersion in Nonaqueous Systems, in Adv. Ceramics, Vol. 21, edited by G. Messing, K. S. Mazdiasni, J.W. McCauley and R.A. Haber (Am. Ceramic Soc., , 1987) pp.323-348.

Google Scholar

[6] B.I. Lee and L.A. Mann, Annual Report to National Science Foundation, Jan. (2001).

Google Scholar

[7] D. Yoon, D and B.I. Lee, J. Ceramic Proc. Res., 3 (2002) 1-8.

Google Scholar

[8] Y. Sakabe, Murata Corp., Kyoto, Japan, Private Communication, (1999).

Google Scholar

[9] X. Wang and B.I. Lee, Colloids and Surfaces, 202 (2002) 71.

Google Scholar

[10] X. Wang, B.I. Lee, B.I., S. Lu, and L.A. Mann, Materials Research Bulletin, 35.

Google Scholar

[15] (2000) 2555-2563.

Google Scholar

[11] T. Reynolds III, Am. Ceram. Soc. Bull., 80.

Google Scholar

[10] (2001) 29.

Google Scholar

[12] S. Lu, and B.I. Lee, Synthesis of Water Redispersible Ferroelectric Nanopowders, presented at the 101st Am. Ceram. Soc., Indianapolis, IN, April 25-28, (1999).

Google Scholar

[13] B.I. Lee, and S. Lu, J. Ceramic Processing Research, 1 (2000) 20-26.

Google Scholar

[14] S. Lu, B.I. Lee, and Z. Wang, Synthesis of Redispersible Nano-Sized Barium Titanate Powders by Hydrothermal Method, in Dielectric Materials & Devices, Ceramic Trans, Vol. 106, edited by K.M. Nair and A. R. Bhalla (Am. Ceram. Soc., Westerville, OH, 2000) pp.5-16.

Google Scholar

[15] S. Lu, B.I. Lee, Z.L. Wang, and W.D. Samuels, J. of Crystal Growth, 219 (2000) 269-276.

Google Scholar

[16] D. Yoon and B.I. Lee, J. Mater. Sci. Mater. in Electronics, in press.

Google Scholar

[17] D. F. K. Hennings, C. Metzmacher and B. S. Schreinemacher, J. Am. Ceram. Soc. 84.

Google Scholar

[1] (2001) 179 - 182.

Google Scholar

[18] X. Wang, B.I. Lee, M. Hu and A. Payzant Kinetics of Nanocrystalline Barium Titanate via Ambient Condition Solution Process, J. Matr. Sci., Materials in Electronics, in press.

Google Scholar

[19] B.I. Lee, X. Wang and M. Hu, Nanocrystal Barium titanate via low temperature ambient pressure conditions, U.S. Patent application in process Feb., (2002).

Google Scholar

[20] X. Wang, B.I. Lee, M. Hu, and A. Payzant, Synthesis of Nanocrystalline Barium Titanate in Various Media via Ambient Condition Sol Process, J. Matr. Sci. Lett., in press.

Google Scholar

[21] R. H. Reuss and B. R. Chalamala, eds., Microelectronics Packaging and Integration, MRS Bull, 28, 11, (2003).

DOI: 10.1557/mrs2003.13

Google Scholar

[22] R. Tumala, P. Chahal, S. Bhattachrya, Recent Advances in Integral Passives at PRC, IMAPS 35th Nordic Conference, Sweden, September (1998).

Google Scholar

[23] Proc. 51st Elec. & Tech. Conf., 2001 Electronic Components and Technology Conference Proc. IEEE, Piscataway, NJ.

Google Scholar

[24] H. Windlass, P. M. Raj, D. Balaraman, S. K. Bhattacharya and R. R. Tummala, Colloidal Processing of Polymer Ceramic Nanocomposites for Integral Capacitors, Proc. of the Intern. Symp. on Adv. Packaging Mater: Processes, Properties and Interfaces, pp.393-398, (2001).

DOI: 10.1109/isaom.2001.916608

Google Scholar

[25] Y. Rao, S. Ogitani, P. Kohl and C. P. Wong, High Dielectric Constant Polymer-Ceramic Composite for Embedded Capacitor Application, Proc. of the Intern. Symp. on Advanced Packaging Materials: Processes, Properties and Interfaces, pp.32-37, (2000).

DOI: 10.1109/isapm.2000.869239

Google Scholar

[26] M.C. Blanco-Lopez, B. Rand and F.L. Riley, J. Eur. Ceram. Soc. 17 (1997) 281-287.

Google Scholar

[27] S. Venigalla, Hydrothermal BaTiO3-based dielectric for BME X7R/X5R MLCC Applications, Center for Dielectric Studies, Spring Meeting, Penn State Univ., April 22- 23, (2002).

Google Scholar

[28] P. Badheka, V. Magadala, and B. I. Lee, Tetragonality and Dielectric Constant of Submicron Sized BT Powders, Am. Ceram. Soc. Annual Meeting, Nashville, TN, April 30, (2003).

Google Scholar