Generalized Vertex Model - Study of Recrystallization in Copper

Krystian Piękoś; Jacek Tarasiuk; Krzysztof Wierzbanowski; Brigitte Bacroix

doi:10.4028/www.scientific.net/MSF.558-559.1157

Paper Titles

Numerical Modelling of Plastic Deformation and Subsequent Recrystallization in Polycrystalline Materials, Based on a Digital Material Framework
p.1133

A New Approach to Model Heterogonous Recrystallization Kinetics Based on the Natural Inhomogeneity of Deformation
p.1139

Preliminary Simulation for Competing Behaviors between Recrystallization and Transformation in Dual Phase Steels
p.1145

Mixed Vertex - Monte Carlo Model of Recrystallization
p.1151

Generalized Vertex Model - Study of Recrystallization in Copper
p.1157

Modeling the Evolution of Orientation Distribution Functions during Grain Growth of some Ti and Zr Alloys
p.1163

Modeling Recrystallization of Aluminum Alloys: A Refined Approach to Particle Stimulated Nucleation
p.1169

Simulation of Ideal Grain Growth Using the Multi-Phase-Field Model
p.1177

Topology Based Growth Law and New Analytical Grain Size Distribution Function of 3D Grain Growth
p.1183

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Generalized Vertex Model - Study of Recrystallization in Copper

Abstract:

Classical vertex model till now described only the grain growth stage and not the primary recrystallization. In the present work the vertex model is first extended in order to take into account the both stages of recrystallization process. The influence of the stored energy is taken into account and some phenomenological laws describing the evolution of grain boundary energy and mobility with misorientation angle are used. Nucleation is considered to be site-saturated. The experimentally determined stored energy values, crystallographic orientations and boundary misorientation distributions are used in order to characterize the initial microstructure. The model is tested to study the recrystallization of 70% and 90% cold rolled polycrystalline copper during an annealing treatment. In order to explain the texture evolution in both cases, it is necessary to introduce an energy threshold for grain boundary movement, i.e. a minimal value of the stored energy difference between a nucleus and the deformed material necessary to provoke grain boundary motion. The developed model is shown to predict texture evolutions in good agreement with experimental data.