Phase-field modelling of grain boundaries ...
Type de document :
Autre communication scientifique (congrès sans actes - poster - séminaire...): Communication dans un congrès sans actes
URL permanente :
Titre :
Phase-field modelling of grain boundaries at equilibrium and under irradiation
Auteur(s) :
Calbert, Yanis [Auteur]
Unité Matériaux et Transformations (UMET) - UMR 8207
Thuinet, Ludovic [Auteur]
Unité Matériaux et Transformations (UMET) - UMR 8207
Messina, Luca [Auteur]
CEA Cadarache
Unité Matériaux et Transformations (UMET) - UMR 8207
Thuinet, Ludovic [Auteur]
Unité Matériaux et Transformations (UMET) - UMR 8207
Messina, Luca [Auteur]
CEA Cadarache
Titre de la manifestation scientifique :
Multiscale Materials Modeling 11
Ville :
Prague (République Tchèque)
Pays :
France
Date de début de la manifestation scientifique :
2024-09-22
Discipline(s) HAL :
Physique [physics]/Matière Condensée [cond-mat]/Science des matériaux [cond-mat.mtrl-sci]
Chimie/Matériaux
Chimie/Matériaux
Résumé en anglais : [en]
Metallic alloys used in nuclear power plants are under permanent irradiation which causes fast modification of their microstructure through a large variety of defects in-teracting with each other: interstitials, vacancies, ...
Lire la suite >Metallic alloys used in nuclear power plants are under permanent irradiation which causes fast modification of their microstructure through a large variety of defects in-teracting with each other: interstitials, vacancies, point defect clusters, dislocations, grain boundaries (GBs), etc. In particular, segregation of atoms in these conditions can be observed at GBs, which can alter the structural integrity of the materials. Despite the numerous improvements achieved so far to understand radiation-induced segrega-tion (RIS) at GBs through cutting-edge experimental or modelling tools, several obser-vations remain unexplained. This might be due to the huge diversity of GB structures and the resulting difficulty to correctly describe their interactions with solute and point defect (PD) diffusion. Recently, phase-field (PF) approaches have been developed to predict RIS behaviour in binary alloys for different conditions. However, in their formalism, the description of GB was still basic since the thermodynamic and elastic properties of the GB and the bulk phase were supposed to be the same, the GB being treated as a simple absorb-ing plane for PDs (“planar sink” model). As a consequence, these approaches fail to predict thermal segregation, which may interplay with RIS resulting in complex seg-regation profile at GBs. On the other side, defect generation due to irradiation is often given at constant rate for vacancies and interstitials in PF modelling, however, other phenomena occur such as ballistic damage, displacement cascade, etc. To overcome the limitations of this “planar sink” model, we first propose in this work to better describe the thermodynamic and elasticity heterogeneities between the bulk phase and the GB. For this purpose, a density-based model recently proposed in the literature is adopted, allowing to recover the well documented “W-shape” segre-gation profile observed experimentally under irradiation. Secondly, we propose bal-listic damage and cascade displacement generation method implementations to our PF model. Case studies will be presented on Fe Cr and nickel base model alloys for nuclear applications.Lire moins >
Lire la suite >Metallic alloys used in nuclear power plants are under permanent irradiation which causes fast modification of their microstructure through a large variety of defects in-teracting with each other: interstitials, vacancies, point defect clusters, dislocations, grain boundaries (GBs), etc. In particular, segregation of atoms in these conditions can be observed at GBs, which can alter the structural integrity of the materials. Despite the numerous improvements achieved so far to understand radiation-induced segrega-tion (RIS) at GBs through cutting-edge experimental or modelling tools, several obser-vations remain unexplained. This might be due to the huge diversity of GB structures and the resulting difficulty to correctly describe their interactions with solute and point defect (PD) diffusion. Recently, phase-field (PF) approaches have been developed to predict RIS behaviour in binary alloys for different conditions. However, in their formalism, the description of GB was still basic since the thermodynamic and elastic properties of the GB and the bulk phase were supposed to be the same, the GB being treated as a simple absorb-ing plane for PDs (“planar sink” model). As a consequence, these approaches fail to predict thermal segregation, which may interplay with RIS resulting in complex seg-regation profile at GBs. On the other side, defect generation due to irradiation is often given at constant rate for vacancies and interstitials in PF modelling, however, other phenomena occur such as ballistic damage, displacement cascade, etc. To overcome the limitations of this “planar sink” model, we first propose in this work to better describe the thermodynamic and elasticity heterogeneities between the bulk phase and the GB. For this purpose, a density-based model recently proposed in the literature is adopted, allowing to recover the well documented “W-shape” segre-gation profile observed experimentally under irradiation. Secondly, we propose bal-listic damage and cascade displacement generation method implementations to our PF model. Case studies will be presented on Fe Cr and nickel base model alloys for nuclear applications.Lire moins >
Langue :
Anglais
Audience :
Internationale
Vulgarisation :
Non
Établissement(s) :
Université de Lille
CNRS
INRAE
ENSCL
CNRS
INRAE
ENSCL
Collections :
Équipe(s) de recherche :
Métallurgie Physique et Génie des Matériaux
Date de dépôt :
2024-11-12T10:04:18Z
2024-11-12T12:20:57Z
2024-11-12T12:20:57Z