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The latest state of simulation techniques to model plasticity and fracture in crystalline materials on the nano- and microscale is presented. Discrete dislocation mechanics and the neighbouring fields molecular dynamics and crystal plasticity are central parts. The physical phenomena, the theoretical basics, their mathematical description and the simulation techniques are introduced and important problems from the formation of dislocation structures to fatigue and fracture from the nano- to microscale as well as it’s impact on the macro behaviour are considered.

Mathematics --- Mathematical physics --- Classical mechanics. Field theory --- Solid state physics --- Physics --- Applied physical engineering --- Engineering sciences. Technology --- Computer. Automation --- ICT (informatie- en communicatietechnieken) --- toegepaste wiskunde --- toegepaste mechanica --- economie --- wiskunde --- ingenieurswetenschappen --- fysica --- mechanica

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This reprint focuses on basic and applied research on fatigue and fracture processes in engineering of materials and composites. Special attention is given to understanding fracture processes from the point of view of micro and nano damage mechanisms related to material microstructure. Advanced experimental methods such as tomography, digital image correlation, high resolution electron microscopy and fractography are applied in combination with theoretical multiscale models based on finite element methods and fracture mechanics to reveal the fundamental causes of material failure.

Mechanical engineering. --- Mechanics, Applied.

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

The latest state of simulation techniques to model plasticity and fracture in crystalline materials on the nano- and microscale is presented. Discrete dislocation mechanics and the neighbouring fields molecular dynamics and crystal plasticity are central parts. The physical phenomena, the theoretical basics, their mathematical description and the simulation techniques are introduced and important problems from the formation of dislocation structures to fatigue and fracture from the nano- to microscale as well as it’s impact on the macro behaviour are considered.

Engineering. --- Continuum Mechanics and Mechanics of Materials. --- Appl.Mathematics/Computational Methods of Engineering. --- Mathematical Methods in Physics. --- Mathematical physics. --- Engineering mathematics. --- Materials. --- Ingénierie --- Physique mathématique --- Mathématiques de l'ingénieur --- Matériaux --- Plasticity --- Fracture mechanics --- Mathematical models --- Fracture mechanics -- Mathematical models. --- Fracture mechanics. --- Mathematical models. --- Plasticity -- Mathematical models. --- Plasticity. --- Engineering & Applied Sciences --- Chemical & Materials Engineering --- Applied Mathematics --- Materials Science --- Crystals --- Plastic properties --- Physics. --- Applied mathematics. --- Continuum mechanics. --- Mechanical engineering. --- Mechanical Engineering. --- Crystallography --- Powders --- Solids --- Mechanics. --- Mechanics, Applied. --- Solid Mechanics. --- Mathematical and Computational Engineering. --- Physical mathematics --- Physics --- Engineering --- Engineering analysis --- Mathematical analysis --- Applied mechanics --- Engineering, Mechanical --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Dynamics --- Quantum theory --- Machinery --- Steam engineering --- Mathematics --- Natural philosophy --- Philosophy, Natural --- Physical sciences --- Plasticity - Mathematical models --- Fracture mechanics - Mathematical models --- Solids. --- Mathematical and Computational Engineering Applications. --- Data processing. --- Solid state physics --- Transparent solids