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A new microstructural model based on dislocation generation and consumption mechanisms through severe plastic deformation

Hosseini, E ; Sharif University of Technology | 2011

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  1. Type of Document: Article
  2. DOI: 10.1016/j.commatsci.2010.11.012
  3. Publisher: 2011
  4. Abstract:
  5. A new model on the evolution of dislocation structure of cell forming metals and alloys through severe plastic deformation is presented. Following previous approaches, the model considers a cellular dislocation structure consisted of two phases: cell interiors and cell walls. The model distinguishes edge and screw dislocations in terms of three categories: mobile dislocations, immobile dislocations in cell interiors and immobile dislocations in cell walls. Then considering physical and geometrical assumptions for each dislocation category, an evolutional law is derived, based on some dislocation interaction mechanisms such as dislocation generation, annihilation, locking and migration. The model is applied on a severe plastic deformation process of aluminum called constrained groove pressing. The outputs of model are detailed description about dislocation densities (densities of edge and screw dislocations of all three mentioned categories) and cell size evolutions during deformation. To verify the results of modeling, X-ray diffraction patterns of deformed samples are analyzed. The achieved dislocation densities and cell sizes from the X-ray tests are compared with that achieved from the model and a good agreement is obtained
  6. Keywords:
  7. Model ; Cell size ; Cell walls ; Constrained groove pressing ; Deformed samples ; Dislocation densities ; Dislocation generation ; Dislocation interaction ; Dislocation structures ; Edge and screw dislocations ; Forming metals ; In-cell ; Microstructural models ; Mobile dislocations ; New model ; Severe plastic deformations ; X-ray patterns ; Aluminum sheet ; Diffraction ; Edge dislocations ; Metallurgy ; Plastic deformation ; Screws ; Walls (structural partitions) ; X ray diffraction ; X rays ; Screw dislocations
  8. Source: Computational Materials Science ; Volume 50, Issue 3 , January , 2011 , Pages 1123-1135 ; 09270256 (ISSN)
  9. URL: http://www.sciencedirect.com/science/article/pii/S0927025610006348