DISLOCATION MULTIPOLES AND THEIR ROLE IN STRAIN-HARDENING,

Abstract

The stress fields of edge dislocation dipoles are able to trap other edge dislocations that approach nearby them. The configurations, energies, and trapping stresses of the resulting tripoles are discussed in some detail. Dipoles may also interact dynamically with approaching dislocations because they cause fluctuating stresses. The decrease in the average velocity of a moving dislocation is given in terms of the fluctuation amplitude and the dislocation's mobility parameter. On the basis of these results, linear strain hardening can be accounted for in terms of edge dislocation dipoles. Since dipoles in real crystals tend to be finite in length and their stress fields attenuate rapidly with distance, they act like particles to impede dislocation motions. Thus hardening is proportional to the dipole concentration which is proportional to the plastic strain, so the hardening will be linear in the strain. Through interactions with approaching dislocations dipoles may become tripoles, then quadrupoles, etc. leading to some of the characteristic residual structures in plastically strained crystals such as: slip bands, deformation bands, bands of secondary slip, ect. (Author)

Document Details

Document Type

Technical Report

Publication Date

Oct 01, 1963

Accession Number

AD0426456

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