![]() Drucker yield criterion for isotropic materials 171ħ.3.1. Problem statement and method of analysis 171ħ.2.1. ![]() Effect of the Third Invariant of the Stress Deviator on the Response of Porous Solids with Pressure-Insensitive Matrix 167 José Luis ALVES and Oana CAZACUħ.2. Anisotropy of the capillary stress contribution 154Ĭhapter 7. DEM description of stress and strains 152Ħ.3. ![]() DEM description of fluid microstructure 149Ħ.2.2. Numerical modeling of wet ideal granular materials 149Ħ.2.1. Stress description within micro-scale volumes and interfaces of triphasic materials 145Ħ.2. Microstructural expression of triphasic total stresses 145Ħ.1.1. Microstructural Views of Stresses in Three-Phase Granular Materials 143 Jérôme DURIEZ, Richard WAN and Félix DARVEĦ.1. Discrete particle simulation of layered compacts 129Ĭhapter 6. Discrete particle simulations of powder compaction 127ĥ.2.2. Discrete Numerical Simulations of the Strength and Microstructure Evolution During Compaction of Layered Granular Solids 123 Bereket YOHANNES, Marcial GONZALEZ and Alberto M. Multiscale Model of Concrete Failure 99 Emir KARAVELI, Mijo NIKOLI and Adnan IBRAHIMBEGOVIĬhapter 5. Anisotropic behavior of 2D pantographic networks versus the degree of nonlinearity 84Ĭhapter 4. Wave dispersion relation in 2D nonlinear periodic structures 81ģ.3.4. Supersonic and subsonic modes for 1D wave propagation 78ģ.3.3. Legendre–Hadamard ellipticity condition and loss of stability 77ģ.3.2. Wave propagation in a nonlinear elastic beam 75ģ.3.1. Expression of the pantographic network energy 70ģ.3. Extensible energy of pantograph for dynamic analysis 70ģ.2.1. Wave Propagation Analysis in 2D Nonlinear Periodic Structures Prone to Mechanical Instabilities 67 Hilal REDA, Yosra RAHALI, Jean-François GANGHOFFER and Hassan LAKISSģ.2. Crystallographic analysis for titanium dwell fatigue 48Ĭhapter 3. Synthetic microstructure generation 46Ģ.2.3. Determining the Probability of Occurrence of Rarely Occurring Microstructural Configurations for Titanium Dwell Fatigue 41 Adam L. ![]() Toward a fatigue model at the scale of the polycrystal 28Ĭhapter 2. 3D mesh generation from tomographic images 20ġ.4.3. Motivation for image-based mechanical computations 19ġ.4.2. Coupling diffraction contrast tomography with the finite-element method. Nanox: a miniature mechanical stress rig designed for near-field X-ray diffraction imaging techniques 16ġ.4. Synchrotron X-ray microtomography 10ġ.2.7. Radon’s transform and reconstruction 8ġ.2.5. X-ray absorption and Beer Lambert’s law 4ġ.2.4. Early days of X-ray computed tomography 3ġ.2.2. 3D X-ray characterization of structural materials 3ġ.2.1. Synchrotron Imaging and Diffraction for In Situ3D Characterization of Polycrystalline Materials 1 Henry PROUDHONġ.2. ![]()
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