Phase field study of acicular growth: Role of elasticity in Widmanstätten structure
暂无分享,去创建一个
[1] M. Dehmas,et al. Isothermal α″ formation in β metastable titanium alloys , 2013 .
[2] C. Cayron. One-step model of the face-centred-cubic to body-centred-cubic martensitic transformation , 2013 .
[3] A. Settefrati,et al. Étude expérimentale et modélisation par champ de phase de la formation de [alpha] dans les alliages de titane [bêta]-métastable , 2012 .
[4] A. D. Backer,et al. Phase-field modeling of precipitate evolution dynamics in elastically inhomogeneous low-symmetry systems: Application to hydride precipitation in Zr , 2012 .
[5] S. Forest,et al. A phase field model incorporating strain gradient viscoplasticity: Application to rafting in Ni-base superalloys , 2012 .
[6] Y. L. Bouar,et al. Phase field methods: Microstructures, mechanical properties and complexity , 2010 .
[7] L. Cheng,et al. Three-dimensional morphology of grain boundary Widmanstätten ferrite in a low carbon low alloy steel , 2010 .
[8] A. Finel,et al. Coupling phase field and viscoplasticity to study rafting in Ni-based superalloys , 2010 .
[9] G. Boussinot,et al. Phase-field modeling of bimodal microstructures in nickel-based superalloys , 2009 .
[10] G. Spanos,et al. The proeutectoid cementite transformation in steels , 2009 .
[11] R. Spatschek,et al. Pattern formation during diffusion limited transformations in solids , 2008, 0811.2723.
[12] Yan Li,et al. On the growth of Widmanstätten precipitates in an Al–Cu alloy , 2008 .
[13] Srikumar Banerjee,et al. Phase transformations : examples from titanium and zirconium alloys , 2007 .
[14] E. Aeby-Gautier,et al. Modelling of phase transformation kinetics in Ti alloys – Isothermal treatments , 2005 .
[15] M. Grant,et al. A phase field model for phase transformation in an elastically stressed binary alloy , 2005 .
[16] J. Ågren,et al. On the formation of Widmanstätten ferrite in binary Fe–C – phase-field approach , 2004 .
[17] Yu U. Wang,et al. The effects of free surfaces on martensite microstructures: 3D phase field microelasticity simulation study , 2004 .
[18] Annick Loiseau,et al. Origin of the complex wetting behavior in Co-Pt alloys , 2003 .
[19] Y. Qi,et al. Unified rationalization of the Pitsch and T-H orientation relationships between Widmanstätten cementite and austenite , 2000 .
[20] D. Banerjee,et al. Field kinetic model and computer simulation of precipitation of L12 ordered intermetallics from f.c.c. solid solution , 1998 .
[21] S. Banerjee,et al. Plate-shaped transformation products in zirconium-base alloys , 1997 .
[22] A. Karma,et al. Quantitative phase-field modeling of dendritic growth in two and three dimensions , 1996 .
[23] M. Fukuhara,et al. Elastic Moduli and Internal Friction of Low Carbon and Stainless Steels as a Function of Temperature , 1993 .
[24] E. Brener,et al. Pattern selection in two-dimensional dendritic growth , 1991 .
[25] W. C. Johnson,et al. Growth of a coherent precipitate from a supersaturated solution , 1988 .
[26] J. Iwan D. Alexander,et al. Interfacial conditions for thermomechanical equilibrium in two‐phase crystals , 1986 .
[27] J. Cahn,et al. A simple model for coherent equilibrium , 1984 .
[28] A. G. Khachaturi︠a︡n. Theory of structural transformations in solids , 1983 .
[29] John W. Cahn,et al. Thermochemical equilibrium of multiphase solids under stress , 1978 .
[30] J. D. Watson,et al. The crystallography of widmanstätten ferrite , 1973 .
[31] G. Purdy. Widmanstätten Precipitation from Non-Ideal Solid Solution: αinβ-CuZn , 1971 .
[32] R. Trivedi,et al. The role of interfacial free energy and interface kinetics during the growth of precipitate plates and needles , 1970, Metallurgical and Materials Transactions B.
[33] H. Aaronson,et al. The dislocation structures of the broad faces of widmanstätten γ plates in an Al-15% Ag alloy , 1967 .
[34] John W. Cahn,et al. Dendritic and spheroidal growth , 1961 .
[35] H. Aaronson,et al. Bainite Reaction in a Plain Carbon Steel , 1955 .