Modeling the Evolution of Orientation Distribution Functions during Grain Growth of some Ti and Zr Alloys

Grzegorz Sawina; Francois Gerspach; Nathalie Bozzolo; Krzystof Sztwiertnia; Anthony D. Rollett; Francis Wagner

doi:10.4028/www.scientific.net/MSF.558-559.1163

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A New Approach to Model Heterogonous Recrystallization Kinetics Based on the Natural Inhomogeneity of Deformation
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HomeMaterials Science ForumMaterials Science Forum Vols. 558-559Modeling the Evolution of Orientation Distribution...

Modeling the Evolution of Orientation Distribution Functions during Grain Growth of some Ti and Zr Alloys

Abstract:

A 2D cellular automaton model developed for the simulation of grain growth in hexagonal metals is presented here. It allows the direct use of experimental measurement as input data. Texture evolution of a titanium alloy and a zirconium alloy are simulated on the basis of simple hypothesis and compared with experimental evolution as well as the results from a 3D Monte Carlo model. Results from both models are discussed with regards to their characteristics.

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Periodical:

Materials Science Forum (Volumes 558-559)

Pages:

1163-1168

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.558-559.1163

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Online since:

October 2007

Authors:

Grzegorz Sawina, Francois Gerspach, Nathalie Bozzolo, Krzystof Sztwiertnia, Anthony D. Rollett, Francis Wagner

Keywords:

Cellular Automaton (CA), Grain Growth, Hexagonal, Modeling, Texture

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References

[1] N. Bozzolo, N. Dewobroto, T. Grosdidier, P. Barberis and F. Wagner : Mat. Sci. For, Vols. 467-470 (2004) p.441.

Google Scholar

[2] N. Dewobroto, N. Bozzolo, P. Barberis and F. Wagner: Int. J. Mat. Res, Vol. 97 (2006), p.826.

Google Scholar

[3] N. Dewobroto: PhD thesis, University of Metz, France, (2004).

Google Scholar

[4] P.A. Beck and P.R. Sperry: Trans. Metal. Soc. AIME Vol. 180 (1949), p.240.

Google Scholar

[5] J.E. Burke and D. Turnbull: Prog. Metal. Phys, Vol. 3 (1952), p.220.

Google Scholar

[6] J. Kroc: Mat. Sci. For, Vol. 482 (2005), p.195.

Google Scholar

[7] H.J. Bunge: Texture analysis in materials science - mathematical methods, Butterworth London (1983).

Google Scholar

[8] N. Bozzolo, N. Dewobroto, T. Grosdidier, F. Wagner: Mat. Sci. Eng. A, Vol. 397 (2005), p.346.

Google Scholar

[9] A.D. Rollett: Crystallographic Texture Change during Grain Growth, JOM, 2004 April, p.63.

DOI: 10.1007/s11837-004-0075-9

Google Scholar

[10] A.D. Rollett and P. Manohar, in: Continuum Scale Simulation of Engineering Materials: Fundamentals-Microstructures-Process Applications, Edited by D. Raabe et al. (2004), p.77.

DOI: 10.1002/3527603786.ch4

Google Scholar