Deformation induced dislocation boundaries: Alignment and effect on mechanical properties

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    Abstract

    The dislocation boundaries formed during cold-rolling of FCC metals have been reported to have a preferred macroscopic direction with respect to the sample axes. However, boundaries have also been reported to form on crystallographic slip planes. The directions of the boundaries formed on crystallographic slip planes are investigated using a newly developed model for formation of such boundaries. It is concluded that these boundaries also lie in the preferred macroscopic direction, i.e. the entire dislocation structure is highly anisotropic. The impact of the anisotropic dislocation structure on the flow stress anisotropy is illustrated by comparison of experimental data and model calculations which take the combined effects of the anisotropic dislocation structure and texture into account. (C) 1997 Elsevier Science B.V.
    Original languageEnglish
    JournalComputational Materials Science
    Volume9
    Issue number1-2
    Pages (from-to)251-260
    ISSN0927-0256
    DOIs
    Publication statusPublished - Dec 1997
    Event6th International Workshop on Computational Mechanics of Materials - Hamburg, Germany
    Duration: 7 Oct 19968 Oct 1996

    Conference

    Conference6th International Workshop on Computational Mechanics of Materials
    Country/TerritoryGermany
    CityHamburg
    Period07/10/199608/10/1996

    Keywords

    • dislocation boundaries
    • anisotropic microstructure
    • flow stress anisotropy
    • texture
    • modelling

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