Dislocations and Plastic Flow in NaCl Single Crystals. I
- 1 July 1962
- journal article
- research article
- Published by AIP Publishing in Journal of Applied Physics
- Vol. 33 (7), 2175-2181
- https://doi.org/10.1063/1.1728923
Abstract
Dislocation multiplication and motion in NaCl was studied using etch pit and birefringence techniques. The observations show that dislocations in glide bands of NaCl are in the form of large concentric loops with sources staggered in the center of the bands. They propagate and multiply by cross‐slip and are braked through intersection jogs. The slip distance parallel to b is estimated to be 2–3 mm and that normal to b 0.5–1 mm, at a stress of 30 g/mm2 in crystals having 5×104 dislocations/cm2. ``Deformation bands'' form normal to the operating system during the latter part of stage I by ``glide polygonization'' of edge dislocations on closely spaced slip planes. These limit dislocation motion to shorter distances in stage II. Stage III appears when significant flow occurs on a secondary system oblique to the primary operating one.Keywords
This publication has 10 references indexed in Scilit:
- Role of Surfaces in Plastic Flow of NaCl Single Crystals. IIJournal of Applied Physics, 1962
- Birefringence due to Dislocations in Glide Bands of Rocksalt Single CrystalsJournal of Applied Physics, 1961
- Dislocation Etch Pit Formation in Sodium ChlorideJournal of Applied Physics, 1961
- Etch Pits at Dislocations in CopperJournal of Applied Physics, 1960
- Behavior of Individual Dislocations in Strain-Hardened LiF CrystalsJournal of Applied Physics, 1960
- Dislocation Multiplication in Lithium Fluoride CrystalsJournal of Applied Physics, 1960
- Strain hardening in face-centred cubic metal crystalsActa Metallurgica, 1954
- Theory of initial stress-strain curves in face-centered metalsActa Metallurgica, 1953
- Laue asterism and deformation bandsActa Crystallographica, 1952
- The Nature of Work-HardeningPhysical Review B, 1952