Fracture of LiF crystals with varied slip geometry
- 18 Downloads
KeywordsVaried Slip Slip Geometry
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
Unable to display preview. Download preview PDF.
- 1.M. T. Sprackling, The Plastic Deformation of Simple Ionic Crystals, Academic Press, London (1976).Google Scholar
- 2.R. J. Stockes, T. L. Johnston, and C. H. Li, “Relationship between plastic flow and the fracture mechanism in magnesium oxide single crystals,” Philos. Mag.,4, No. 44, 920–932 (1959).Google Scholar
- 3.V. A. Stepanov, “Role of deformation in the process of fracture of solids,” in: Problems of Strength and Plasticity of Solids [in Russian], Nauka, Leningrad (1979), pp. 10–26.Google Scholar
- 4.B. I. Smirnov, “Mechanical characteristics and dislocation structure of LiF crystals deformed by slip in a single system of crystallographic planes,” in: Fiz. Tverd. Tela,10, No. 9, 2689–2696 (1968).Google Scholar
- 5.J. S. Nadeau, “Radiation hardening in alkali halide crystals,” J. Appl. Phys.,35, No. 4, 1248–1255 (1964).Google Scholar
- 6.R. L. Fleisher and B. Chalmers, “Grip effects in the deformation of single crystals,” J. Mech. Phys, Solid.,6, No. 4, 307–313 (1958).Google Scholar
- 7.S. P. Timoshenko, Resistance of Materials [in Russian], Vol. 1, Fizmatgiz, Moscow (1960).Google Scholar
- 8.O. V. Klyavin, T. V. Samoilova, B. I. Smirnov, et al., “Microstructure of the surface of LiF single crystals deformed at 4.2°K,” in: Materials of the Ninth All-Union Conf. on Electron Microscopy (Tbilisi, Oct. 28–Nov. 3, 1973) [in Russian], Moscow (1973), pp. 71–72.Google Scholar
© Plenum Publishing Corporation 1982