Computer Simulations and Statistical Theory of Normal Grain Growth in Two and Three Dimensions

Dana Zöllner; Peter Streitenberger

doi:10.4028/www.scientific.net/MSF.467-470.1129

Paper Titles

Simulating the Interaction between a Straight Boundary and a Particle
p.1105

The Von Neumann-Mullins Theory of Grain Growth – Valid or Not?!
p.1111

Monte Carlo Method for Simulating Grain Growth in 3D Influence of Lattice Site Arrangements
p.1117

On the Nucleation of Abnormal Grain Growth: A 2D Vertex Simulation
p.1123

Computer Simulations and Statistical Theory of Normal Grain Growth in Two and Three Dimensions
p.1129

The Role of Recrystallization and Coarsening in the Formation of Ultrafine Grained Steels through Thermomechanical Processing
p.1137

Geometric Dynamic Recrystallization in α-Zirconium at Elevated Temperatures
p.1145

Dynamic Recrystallization of Zircaloy-4 during Working within the Upper α-Range
p.1151

Softening Mechanisms in Two Duplex Stainless Steels Deformed in Hot Torsion
p.1157

HomeMaterials Science ForumMaterials Science Forum Vols. 467-470Computer Simulations and Statistical Theory of...

Computer Simulations and Statistical Theory of Normal Grain Growth in Two and Three Dimensions

Abstract:

A modified Monte Carlo algorithm for single-phase normal grain growth is presented, which allows one to simulate the time development of the microstructure of very large grain ensembles in two and three dimensions. The emphasis of the present work lies on the investigation of the interrelation between the local geometric properties of the grain network and the grain size distribution in the quasi-stationary self-similar growth regime. It is found that the topological size correlations between neighbouring grains and the resulting average statistical growth law both in two and three dimensions deviate strongly from the assumptions underlying the classical Lifshitz- Sloyzov-Hillert theory. The average local geometric properties of the simulated grain structures are used in a statistical mean-field theory to calculate the grain size distribution functions analytically. By comparison of the theoretical results with the simulated grain size distributions it is shown how far normal grain growth in two and three dimensions can successfully be described by a mean-field theory and how stochastic fluctuations in the average growth law must be taken into account.