Recrystallization and Grain Growth

Numerical modeling of recrystallization and grain growth by different approaches.

References

Further details on modeling and simulation of recrystallization and grain growth phenomena can be found in:

• H. Hallberg, A. Chamanfar and N. Nanninga, A constitutive model for the flow stress behavior and microstructure evolution in aluminum alloys under hot working conditions - with application to AA6099, Applied Mathematical Modelling, 81C:253-262, 2020
• H. Hallberg and Vasily V. Bulatov, Modeling of grain growth under fully anisotropic grain boundary energy, Modelling and Simulation in Materials Science and Engineering, 27(4):045002, 2019
• Y. Mellbin, H. Hallberg and M. Ristinmaa, An extended vertex and crystal plasticity framework for efficient multiscale modeling of polycrystalline materials, International Journal of Solids and Structures, 125:150-160, 2017
• H. Hallberg, F. Adamski, S. Baiz and O. Castelnau, Microstructure and property modifications of cold rolled IF steel by local laser annealing, Metallurgical and Materials Transactions A, 48(10):4786-4802, 2017
• Y. Mellbin, H. Hallberg and M. Ristinmaa, Recrystallization and texture evolution during hot rolling of copper, studied by a multiscale model combining crystal plasticity and vertex models, Modelling and Simulation in Materials Science and Engineering, 24(7):075004, 2016
• H. Hallberg and P.A.T. Olsson, Investigation of microstructure evolution during self-annealing in thin Cu films by combining mesoscale level set and ab-initio modeling, Journal of the Mechanics and Physics of Solids, 90:160-178, 2016
• Y. Mellbin, H. Hallberg and M. Ristinmaa, A combined crystal plasticity and graph-based vertex model of dynamic recrystallization at large deformations, Modelling and Simulation in Materials Science and Engineering, 23(4):045011, 2015
• H. Hallberg, Influence of anisotropic grain boundary properties on the evolution of grain boundary character distribution during grain growth - A 2D level set study, Modelling and Simulation in Materials Science and Engineering, 22(8):085005, 2014
• H. Hallberg, B. Svendsen, T. Kayser and M. Ristinmaa, Microstructure evolution during dynamic discontinuous recrystallization in particle-containing Cu, Computational Materials Science, 84:327-338, 2014
• H. Hallberg, A modified level set approach to 2D modeling of dynamic recrystallization, Modelling and Simulation in Materials Science and Engineering, 21(8):085012, 2013
• H. Hallberg, Influence of process parameters on grain refinement in AA1050 aluminum during cold rolling, International Journal of Mechanical Sciences, 66C:260-272, 2013
• H. Hallberg, Approaches to modeling of recrystallization, Metals, 1(1):16-48, 2011
• H. Hallberg, M. Wallin and M. Ristinmaa, Simulation of discontinuous dynamic recrystallization in pure Cu using a probabilistic cellular automaton, Computational Materials Science, 49:25-34, 2010
• H. Hallberg, M. Wallin and M. Ristinmaa, Modeling of continuous dynamic recrystallization in commercial-purity aluminum, Materials Science and Engineering A, 572:1126-1134, 2010