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Mechanical microstructural evolution

However, there have been a number of reports of athermal effects in processing ceramic materials, where the sintering rate or the microstructure evolution (grain size and/or porosity) resulting from microwave heating differed from that obtained by a conventional heat treatment at the same temperature. Thus, athermal effects refer to mechanisms that operate in addition to the conventional thermal effects and may be a function of, for example, the electric field intensity or the frequency. [Pg.1696]

The stated considerations are correct for titanium. In titanium alloys evolution of lamellar microstructure (typical for titanium alloys) takes place due to development of globularization [8], The process develops by means of substructure formation in the lamellas of phases, division of lamellas and transformation of lamellas parts into globular particles. Keep the process its main features in the case of SMC structure formation There are no such investigations in the scientific literature. The relative simplicity of the method and its commercial application bring up a question to investigate the features of microstructure evolution and mechanical behavior of titanium and its alloys during successive deformation/rotation of samples as well as scale up process capability for production of SMC structure in large-scale billets and sheets. [Pg.402]

Microstructure Evolution and Mechanical Behavior of Ti-64 Alloy During ABC Deformation. [Pg.406]

P. F. Becher, G. S. Painter, N. Shibata, S. B. Waters, H-T. Lin, Effects of rare-earth (RE) intergranular adsorption on the phase transformation, microstructure evolution, and mechanical properties in silicon nitride with RE203 4- MgO additives RE=La, Gd, and Lu, 7. Amer. Ceram. Soc., 91 [7], 2328-2336, (2008). [Pg.38]

F Lofaj, Creep mechanism and microstructure evolution in silicon nitride ceramics, Int. J. Mater. Product Tech., 28, 487-513 (2007). [Pg.38]

H. Park and H. Kim, Microstructure Evolution and Mechanical Properties of SijN4 with Yb20]as a Sintering Additive, J. Am. Ceram. Soc., 80, 750-56(1997). [Pg.296]

P.R. Subramanian, N.V. Nirmalan, L.M. Young, P. Sudkamp, M. Larsen, P.L. Dupree, and A.K. Shukla, Effect of Microstructural Evolution in Mechanical and Corrosion Behavior of Friction Stir-Processed Aluminum Alloys, Friction Stir Welding and Processing II, K.V. Jata, M.W. Mahoney, R.S. Mishra, S.L. Semi-... [Pg.28]

C. Gallais, A. Denquin, A. Pic, A. Simar, T. Pardoen, and Y. Brechet, Modelling the Relationship between Process Parameters, Microstructural Evolutions and Mechanical Behavior in a Friction Stir Welded 6xxx Aluminum Alloy, Proc. Fifth Int. Symp. on Friction Stir Welding, Sept 2004 (Metz, France), TWI... [Pg.217]

Panza-Giosa R, Embury D, Wang Z (2006) Microstructure evolution and mechanical properties in Ti-5Al-5V-5Mo-3Cr after solution heat treatment and ageing in the alpha-beta range. In Seminar Roque, 2006. http //coursenotes.mcmaster.ca/ 701-702 Seminars/2006-2007/702 Roque Panza-Giosa Sept 20 07.pdf Accessed 10 Jun 2013... [Pg.889]

Tamer El-Raghy and Michel W. Barsoum, Processing and Mechanical Properties of Ti3SiC2 I, Reaction Path and Microstructure Evolution,./. Am. Ceram. Soc. 82 (10), 2849 (1999). [Pg.29]

Tian, H.H., and Atzmon, M., Kinetics of microstructure evolution in nanocrystalline Fe powder during mechanical attrition, Acta Mater., 47 (4), 1255-1261, 1999. [Pg.458]

Chung, U.-J., Kim, D.-Y, and Hwang, N.-M. (2002) Microstructural evolution during sintering of H02/Si02-doped alumina mechanism of anisotropic... [Pg.527]

C. Labrug re, A. Guette and R. Naslain, Mechanical behavior and microstructural evolution of thermally aged 2D-SIC (ex-PCS)/C/SiC composites. Revue Composites et Materiaux Avanc s, Vol. 3, Hors Serie, J.L. Chermantand G. Fantozzi, eds., Hermes, 1993, Paris, 91-111 (1993). [Pg.297]

Del6glise, R, Berger, M.H. and Bunsell, A.R. (2002) Microstructural evolution under load and high temperature deformation mechanisms of a mullite/alumina fibre. J. Eur. Ceram. Soc., 22 1501. [Pg.105]

V.P.Pavlovic, M.V.Nikolic, V.B.Pavlovic, N. Labus, Lj. Zivkovi, B.D.Stojanovic, Correlation between densification rate and microstructure evolution of mechanically activated BaTiOj, Ferroelectries 319 (2005) 75-85... [Pg.86]

Grujicic M, et al. Multi-length scale modeling and analysis of microstructure evolution and mechanical properties in polyurea. J Mater Sci 2011 46(6) 1767-79. [Pg.21]

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See also in sourсe #XX -- [ Pg.52 , Pg.53 ]



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