Anisotropic Elasticity Solutions for Dislocation Barriers in Face-Centered Cubic Crystals
- 1 August 1965
- journal article
- research article
- Published by AIP Publishing in Journal of Applied Physics
- Vol. 36 (8), 2400-2406
- https://doi.org/10.1063/1.1714498
Abstract
The stability of extended dislocation barriers in face‐centered cubic metals is determined using the theory of anisotropic elasticity. It is found that the results typically differ from the isotropic elasticity solution by 25%, but the difference can in special cases amount to as much as a factor of four. The anisotropic results are in qualitative agreement with earlier isotropic results in predicting the relative strength of the barriers to dislocation glide. The results suggest that the measurement of barrier extension should provide the most accurate available means of estimating the stacking‐fault energy in fcc metals.Keywords
This publication has 20 references indexed in Scilit:
- Climb-Barrier to Dislocation Glide in fcc CrystalsJournal of Applied Physics, 1962
- Theory of Extended Dislocations in Symmetry Directions in Anisotropic Infinite Crystals and Thin PlatesJournal of Applied Physics, 1962
- Direct measurements of stacking-fault energies from observations of dislocation nodesPhilosophical Magazine, 1961
- On Dislocation Interactions in the fcc LatticeJournal of Applied Physics, 1961
- Dislocation interactions in face-centred cubic metals, with particular reference to stainless steelProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1959
- LI. The strength of homer-cottrell sessile dislocationsPhilosophical Magazine, 1956
- Dislocation Nodes in Face-Centred Cubic LatticesProceedings of the Physical Society. Section B, 1953
- Anisotropic elasticity with applications to dislocation theoryActa Metallurgica, 1953
- LX. The formation of immobile dislocations during slipJournal of Computers in Education, 1952
- A dislocation reaction in the face-centred cubic latticeJournal of Computers in Education, 1951