Add to ORKGIn this work, a physically based self-consistent model is developed and employed to examine the microscopic lattice response of pre-strained Type 316H polycrystalline austenitic stainless steel subjected to uniaxial tensile and compressive loading. The model is also used to explain the Bauschinger effect observed at the macroscopic length-scale. Formulated in a crystal based plasticity framework, the model incorporates detailed strengthening effects associated with different microstructural elements such as forest dislocation junctions, solute atoms and precipitates on individual crystallographic slip planes of each individual grain within the polycrystal. The elastoplastic response of the bulk polycrystal is obtained by homogenizing the re...
peer-reviewedThe micromechanical deformation of an austenitic stainless steel under uniaxial tension...
In the present study the Hu-Cocks micromechanical model [1,2] for dislocation-obstacle interactions,...
Metastable austenitic stainless steel will transform to martensite when subjected to mechanical work...
In this work, a physically based self-consistent model is developed and employed to examine the micr...
International audienceThe generation of internal stresses/strains arising from mechanical deformatio...
There is a long and lively debate in the literature about the origin of the Bauschinger effect in po...
The role of misfit stress in kinematic hardening under reversed straining of a Type 316H austenitic ...
A combined thermodynamic/kinetic approach is adopted to derive the climbcontrolled recovery of dislo...
The residual stresses in materials have a considerable effect on the mechanical properties, includin...
Individual anisotropic grains within a polycrystalline material exhibit different micro-mechanical r...
We propose a multi-scale modeling approach that can simulate the microstructural and mechanical beha...
The lattice strain and intensity evolution obtained from in-situ neutron diffraction experiments of ...
AbstractThe development and validation of crystal plasticity models requires the ability to map defo...
Additively manufactured (AM) metallic materials commonly possess substantial microscale internal str...
International audienceThe refinement of grains in a polycrystalline material leads to an increase in...
peer-reviewedThe micromechanical deformation of an austenitic stainless steel under uniaxial tension...
In the present study the Hu-Cocks micromechanical model [1,2] for dislocation-obstacle interactions,...
Metastable austenitic stainless steel will transform to martensite when subjected to mechanical work...
In this work, a physically based self-consistent model is developed and employed to examine the micr...
International audienceThe generation of internal stresses/strains arising from mechanical deformatio...
There is a long and lively debate in the literature about the origin of the Bauschinger effect in po...
The role of misfit stress in kinematic hardening under reversed straining of a Type 316H austenitic ...
A combined thermodynamic/kinetic approach is adopted to derive the climbcontrolled recovery of dislo...
The residual stresses in materials have a considerable effect on the mechanical properties, includin...
Individual anisotropic grains within a polycrystalline material exhibit different micro-mechanical r...
We propose a multi-scale modeling approach that can simulate the microstructural and mechanical beha...
The lattice strain and intensity evolution obtained from in-situ neutron diffraction experiments of ...
AbstractThe development and validation of crystal plasticity models requires the ability to map defo...
Additively manufactured (AM) metallic materials commonly possess substantial microscale internal str...
International audienceThe refinement of grains in a polycrystalline material leads to an increase in...
peer-reviewedThe micromechanical deformation of an austenitic stainless steel under uniaxial tension...
In the present study the Hu-Cocks micromechanical model [1,2] for dislocation-obstacle interactions,...
Metastable austenitic stainless steel will transform to martensite when subjected to mechanical work...