Effects of Applied Stress and Heating Rate in Field Assisted Sintering
作者: Olivier Guillon
DOI: 10.1007/978-3-642-31009-6_9
关键词: Materials science 、 Stress (mechanics) 、 Microstructure 、 Mechanical pressure 、 Sintering 、 Field (physics) 、 Mechanical engineering 、 Oxide ceramics 、 Process (computing)
摘要: In the previous chapters we have mainly described effects of electrical field on densification behavior when using Field Assisted Sintering. addition to those effects, Sintering also offers possibility applying a mechanical pressure as well high heating rates during sintering. The result is significant change in sintering process. That is, gone through description conventional initial this book, and there great temptation use that theory directly understand SPS. But comparing free SPS like performances two ways transportation such bicycle motorcycle. first one relies natural driving force (the rider’s muscles), second gets further energy from attached engine. translation movement obtained rotation wheels same but kinetics possibly final destination are not! Therefore, present chapter aims at reviewing separate contributions applied stress rate microstructure development oxide ceramics. Carefully-designed experiments coupled with physical understanding enable us figure out real advantages drawbacks technique extend its possibilities.
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sci-hub.se 参考文章(87)
Ruzhong Zuo, Jürgen Rödel, Temperature dependence of constitutive behaviour for solid-state sintering of alumina Acta Materialia. ,vol. 52, pp. 3059- 3067 ,(2004) , 10.1016/J.ACTAMAT.2004.03.008
Rachman Chaim, Zhijian Shen, Grain size control by pressure application regime during spark plasma sintering of Nd-YAG nanopowders Journal of Materials Science. ,vol. 43, pp. 5023- 5027 ,(2008) , 10.1007/S10853-008-2742-7
R.K. Bordia, G.W. Scherer, On constrained sintering—I. Constitutive model for a sintering body Acta Metallurgica. ,vol. 36, pp. 2393- 2397 ,(1988) , 10.1016/0001-6160(88)90189-7
Olivier Guillon, Jochen Langer, Master sintering curve applied to the Field-Assisted Sintering Technique Journal of Materials Science. ,vol. 45, pp. 5191- 5195 ,(2010) , 10.1007/S10853-010-4556-7
Eugene A. Olevsky, Theory of sintering: from discrete to continuum Materials Science & Engineering R-reports. ,vol. 23, pp. 41- 100 ,(1998) , 10.1016/S0927-796X(98)00009-6
Eugene A. Olevsky, Sastry Kandukuri, Ludo Froyen, Consolidation enhancement in spark-plasma sintering: Impact of high heating rates Journal of Applied Physics. ,vol. 102, pp. 114913- ,(2007) , 10.1063/1.2822189
J.F Roy, M Descemond, C Brodhag, F Thevenot, Alumina microstructural behaviour under pressureless sintering and hot-pressing Journal of The European Ceramic Society. ,vol. 11, pp. 325- 333 ,(1993) , 10.1016/0955-2219(93)90032-M
J.M. Montes, F.G. Cuevas, J. Cintas, A new expression for the effective pressure on powders under compression Computational Materials Science. ,vol. 36, pp. 329- 337 ,(2006) , 10.1016/J.COMMATSCI.2005.04.008
R. L. COBLE, J. S. ELLIS, Hot‐Pressing Alumina—Mechanisms of Material Transport Journal of the American Ceramic Society. ,vol. 46, pp. 438- 441 ,(1963) , 10.1111/J.1151-2916.1963.TB11771.X
T. VASILOS, R. M. SPRIGGS, Pressure Sintering: Mechanisms and Microstructures for Alumina and Magnesia Journal of the American Ceramic Society. ,vol. 46, pp. 493- 496 ,(1963) , 10.1111/J.1151-2916.1963.TB13781.X