Add to ORKGA continuum model of plasticity, Phenomenological Mesoscopic Field Dislocation Mechanics (PMFDM), is used to study the effect of surface passivation, grain orientation, grain boundary constraints, and film thickness on the mechanical response of multicrystalline thin films. The numerical experiments presented in this paper show that a surface passivation layer on thin films introduces thickness dependence of the mechanical response. However, the effect of passivation decreases in films with impenetrable grain boundaries. The orientation of individual grains of the multicrystal also has a significant effect on the mechanical response. Our results are in qualitative agreement with experimental observations. A primary contribution of this work...
A line tension approach is reviewed to model slip transfer across tilt grain boundaries (GBs). It is...
Three-dimensional dislocation dynamics simulations were used to examine the role of surface passivat...
Stress development and relaxation in polycrystalline thin films perfectly bonded to a stiff substrat...
A continuum model of plasticity, Phenomenological Mesoscopic Field Dislocation Mechanics (PMFDM), is...
A continuum model of plasticity, Mesoscopic Field Dislocation Mechanics (MFDM), is used to study the...
A continuum model of plasticity, Mesoscopic Field Dislocation Mechanics (MFDM), is used to study the...
This work involves the modeling and understanding of mechanical behavior of crystalline materials us...
A framework for modeling controlled plastic flow through grain boundaries using a continuum plastic...
AbstractThe uniaxial tension behavior of polycrystalline thin films, in which all grain boundaries (...
Discrete dislocation dynamics simulations are carried out to systematically investigate the microstr...
3-D discrete dislocation dynamics simulations were used to investigate the size-dependent plasticity...
Discrete dislocation dynamics simulations are carried out to systematically investigate the microstr...
Plastic deformation in crystalline materials is mediated by dislocation motion and their interaction...
The tensile response of single crystal films passivated on two sides is analysed using climb enabled...
A line tension approach is reviewed to model slip transfer across tilt grain boundaries (GBs). It is...
Three-dimensional dislocation dynamics simulations were used to examine the role of surface passivat...
Stress development and relaxation in polycrystalline thin films perfectly bonded to a stiff substrat...
A continuum model of plasticity, Phenomenological Mesoscopic Field Dislocation Mechanics (PMFDM), is...
A continuum model of plasticity, Mesoscopic Field Dislocation Mechanics (MFDM), is used to study the...
A continuum model of plasticity, Mesoscopic Field Dislocation Mechanics (MFDM), is used to study the...
This work involves the modeling and understanding of mechanical behavior of crystalline materials us...
A framework for modeling controlled plastic flow through grain boundaries using a continuum plastic...
AbstractThe uniaxial tension behavior of polycrystalline thin films, in which all grain boundaries (...
Discrete dislocation dynamics simulations are carried out to systematically investigate the microstr...
3-D discrete dislocation dynamics simulations were used to investigate the size-dependent plasticity...
Discrete dislocation dynamics simulations are carried out to systematically investigate the microstr...
Plastic deformation in crystalline materials is mediated by dislocation motion and their interaction...
The tensile response of single crystal films passivated on two sides is analysed using climb enabled...
A line tension approach is reviewed to model slip transfer across tilt grain boundaries (GBs). It is...
Three-dimensional dislocation dynamics simulations were used to examine the role of surface passivat...
Stress development and relaxation in polycrystalline thin films perfectly bonded to a stiff substrat...