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Last update: T_KFK (22.05.2003)
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Last update: doc. Dr. rer. nat. Robert Král, Ph.D. (09.06.2019)
The credit is issued based on the attendance at tutorials and passing of one or two written tests.
Final exam has to be passed. The credit is necessary for taking the exam, if not stated otherwise by the lecturer.
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Last update: RNDr. Jana Šmilauerová, Ph.D. (21.02.2022)
D. Hull, D. J. Bacon: Introduction to Dislocations, Butterworth-Heinemann, 2001. R. Abbaschian, L. Abbaschian, R. E. Reed-Hill: Physical Metallurgy Principles, Cengage Learning, 2009. D. R. Askeland, P. P. Fulay, W. J. Wright: The Science and Engineering of Materials, Cengage Learning, 2011. R. E. Smallman, A. H. W. Ngan: Physical Metallurgy and Advanced Materials, Butterworth-Heinemann, 2011. M. A. Meyers, K. K. Chawla: Mechanical Metallurgy - principles and applications, Prentice-Hall, Inc., 1984. G. E. Dieter: Mechanical Metallurgy, McGraw-Hill, 1988. G. Gottstein: Physical Foundations of Materials Science, Springer, 2004. |
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Last update: doc. Dr. rer. nat. Robert Král, Ph.D. (09.06.2019)
Requirements for the exam correspond to the annotation/syllabus.
The exam is oral. |
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Last update: T_KFK (22.05.2003)
1. Geometry of plastic deformation. 2. Plastic deformation of single crystals. 3. Thermally activated dislocation motion. 4. Solid solution hardenig. 5. Strain hardening 6. Hardening in multicomponent systems. 7. Deformation of polycrystals. 8. Plastic deformation at very low temperatures. 9. Twinning. |