4.7 Article

Incorporating point defect generation due to jog formation into the vector density-based continuum dislocation dynamics approach

期刊

出版社

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.jmps.2021.104609

关键词

Continuum dislocation dynamics; Dislocation jogs; Point defects; Finite element method

资金

  1. Naval Nuclear Laboratory
  2. US Department of Energy, Office of Science, Division of Materials Sciences and Engineering at Purdue University [DE-SC0017718]
  3. U.S. Department of Energy (DOE) [DE-SC0017718] Funding Source: U.S. Department of Energy (DOE)

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The detailed model for jog formation and transport during plastic deformation of crystalline materials was developed within the vector density-based continuum dislocation dynamics framework, with a focus on the balance equations for point defect generation associated with jog transport. Results showed an asymmetry in vacancy and interstitial generation, and coupling the point defect generation mechanism to dislocation dynamics led to a higher hardening rate and dislocation density.
During plastic deformation of crystalline materials, point defects such as vacancies and interstitials are generated by jogs on moving dislocations. A detailed model for jog formation and transport during plastic deformation was developed within the vector density-based continuum dislocation dynamics framework (Lin and El-Azab, 2020; Xia and El-Azab, 2015). As a part of this model, point defect generation associated with jog transport was formulated in terms of the volume change due to the non-conservative motion of jogs. Balance equations for the vacancies and interstitials including their rate of generation due to jog transport were also formulated. A two-way coupling between point defects and dislocation dynamics was then completed by including the stress contributed by the eigen-strain of point defects. A jog drag stress was further introduced into the mobility law of dislocations to account for the energy dissipation during point defects generation. A number of test problems and a fully coupled simulation of dislocation dynamics and point defects generation and diffusion were performed. The results show that there is an asymmetry of vacancy and interstitial generation due to the different formation energies of the two types of defects. The results also show that a higher hardening rate and a higher dislocation density are obtained when the point defect generation mechanism is coupled to dislocation dynamics.

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