Continuum Scale Simulation of Engineering Materials

Introduction

FUNDAMENTALS AND BASIC METHODS

Computational Thermodynamics and Kinetics without Phase Fileds (Thermocalc, Dictra, etc.)

Phase Field Method

Fluid Materials Dynamics

Cellular Automata and Lattice Gas Automata

Dislocation Dynamics

Potts Type models

Crystal Plasticity

Artificial Neural Networks

Scaling, Coarse Graining and Renormalization

APPLICATION TO ENGINEERING MICROSTRUCTURES

Phase Field Simulation of Solidification

Modeling Dendrititc Structures

Numerical Simulation of Continuous and Investment Casting

Phase Field Simulation of Solid-state Phase Transformations and Strain/stress-dominated Microstructure Evolution

From Microscopic to Semi-Macroscopic Polymer Simulations

Statistical Theory of Grain Growth

Curvature Driven Grain Growth

Potts Modeling of Grain Growth and Recrystallization

Cellular Automaton Simulation

Vertex Grain Boundary Modeling

Thermal Activation in Discrete Dislocation Dynamics

3D Discrete Dislocation Dynamics

Discrete Dislocation Dynamics in Thin Layers

Coarse Graining of Dislocation Dynamics

Statistical Dislocation Modeling

Taylor-type Homogenization Methods for Texture and Anisotropy

Micromechanics of Filled Polymers

Continuum Thermodynamic Modelling of Additional Hardening

Strain Gradient Theory

Yield Surface Plasticity

Crystal Plasticity Finite Element Method

Texture Component Crystal Plasticity Finite Element Method

Creep Simulation (Turbine)

Micromechanical Simulation of Composites

3D Elastodynamics of Cracking

Computational Fracture Mechanics

APPLICATION TO MATERIALS PROCESSES

Artificial Neural Networks

Integration of Physically Based Materials Concepts

The Multiphysics Modeling of Solidification and Melting Processes

Simulation of Casting and Solidification Proceses

Integrated Simulation of Multistep Rolling Processes

Forming Analysis and Design

Extrusion

Sheet Springback

Sheet

Professor Dierk Raabe received his Ph.D. (1992) and habilitation (1997) at RWTH Aachen, Germany, in the fields of Physical Metallurgy and Metal Physics. He is currently Director and Executive at the Max-Planck Institut für Eisenforschung, Düsseldorf, Germany, after working some time as researcher at Carnegie Mellon University, USA, the High Magnetic Field Laboratory in Tallahassee, USA, and serving as senior researcher and lecturer at the Institut für Metallkunde und Metallphysik, RWTH Aachen, Germany. His research fields are computer simulation of materials, composites, textures, and micromechanics, in which he authored more than 100 papers in peer-reviewed magazines and three books. He teaches various courses on computational materials science, materials mechanics, history of metals, and textures at RWTH Aachen (Germany) and at Carnegie Mellon University Pittsburgh (USA). His work was already awarded with several prizes, among them the Adolf-Martens Award, Masing Award, Heisenberg Award, and the Leibniz Award.
Dr. Franz Roters studied Physics in Braunschweig, where he got his diploma degree in 1993. From 1994 to 1998 he was scientist at the Institute for Metal Physics and Physical Metallurgy at the RWTH Aachen. He got his PhD. degree in 1999 in the field of constitutive modelling of aluminium. From 1999 till 2000 he was researcher at the R&D centre of VAW (today Hydro Aluminium Deutschland GmbH) in Bonn. Since 2000 he is senior scientist at the Max-Planck-Institut für Eisenforschung in Düsseldorf, where he is the leader of the research group "Theory and Simulation" in the department for Microstructure Physics and Metal Forming. Dr. Roters published more than 30 papers in the field of constitutive modelling and simulation of forming. He is head of the Technical Committee "Computersimulation" of the Deutsche Gesellschaft für Materialkunde e.V. (DGM).

Professor Long-Qing Chen is teaching Materials Science and Engineering at Penn State. He received his B.S. in

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