Prediction of hardening effect by irradiation-induced vacancy clusters with dislocation dynamics

•A vacancy cluster (VC)-dislocation interaction model is established using Eshelby's equivalent inclusion method.•The hardening effect of randomly distributed VCs with high density is comprehensively studied by DD simulations.•A new hardening model with no free parameter is proposed to predict...

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Bibliographic Details
Published in:International journal of plasticity 2022-02, Vol.149, p.103160, Article 103160
Main Authors: Wu, Kaitao, Liu, Guisen, Yu, Ping, Ye, Changqing, Shi, Jiaqing, Shen, Yao
Format: Article
Language:English
Subjects:
Clusters
Density
Dislocation
Dislocation dynamics
Dislocation loops
Freeware
Interaction models
Irradiation hardening
Mechanical analysis
Parameter modification
Precipitates
Radiation dosage
Size distribution
Tungsten
Vacancies
Vacancy cluster
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Summary:•A vacancy cluster (VC)-dislocation interaction model is established using Eshelby's equivalent inclusion method.•The hardening effect of randomly distributed VCs with high density is comprehensively studied by DD simulations.•A new hardening model with no free parameter is proposed to predict hardening effects of VCs based on DD simulation results.•The new hardening model exhibits good accuracy in predicting VC-induced hardening when comparing with experiments. Development of irradiation hardening models attracts extensive attention in designing nuclear materials. Dislocation dynamics (DD) method is a powerful tool in this field for its advantages of predicting mechanical response with microstructural changes such as dislocation evolution, and its extendibility by incorporating the hardening mechanisms, i.e., the dislocation motion impeded by irradiation-induced defects such as vacancy/interstitial clusters, dislocation loops, precipitates etc. Focusing on the hardening effect contributed by vacancy cluster (VC) that is of high number density even at low irradiation dose, this work develops a VC-dislocation interaction model based on Eshelby's equivalent inclusion method. Specifically, a VC is treated as an inclusion with a certain eigenstrain that gives zero stress inside the VC at the presence of dislocation. By adding the interaction force between VC and dislocation derived using the eigenstrain to dislocation force, we implement this model in open-source DD software ParaDiS. Further, we apply the model to investigate the hardening effect by VCs with varying size and number density. Simulation results show that the hardening by VCs of different sizes is all proportional to the 2/3 power of total number density. To further quantify the hardening effect of VCs, we propose a hardening model which modifies the previous Frediel-Kroupa-Hirsch (FKH) model by making the hardening coefficient in linear relation with VC diameter and introducing an effective diameter that account for size distribution of VCs. The MFKH (modified FKH) model with no free parameter shows good accuracy in predicting VC induced hardening in tungsten comparing with experiments.
ISSN:0749-6419
1879-2154
DOI:10.1016/j.ijplas.2021.103160