ČERNÝ, Miroslav, P. ŠESTÁK, J. POKLUDA and Mojmír ŠOB. Shear instabilities in perfect bcc crystals during simulated tensile tests. Physical Review B. The American Physical Society, 2013, vol. 87, No 1, p. "nestránkováno", 4 pp. ISSN 1098-0121. Available from: https://dx.doi.org/10.1103/PhysRevB.87.014117.
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Basic information
Original name Shear instabilities in perfect bcc crystals during simulated tensile tests
Authors ČERNÝ, Miroslav (203 Czech Republic, guarantor), P. ŠESTÁK (203 Czech Republic), J. POKLUDA (203 Czech Republic) and Mojmír ŠOB (203 Czech Republic, belonging to the institution).
Edition Physical Review B, The American Physical Society, 2013, 1098-0121.
Other information
Original language English
Type of outcome Article in a journal
Field of Study 10302 Condensed matter physics
Country of publisher United States of America
Confidentiality degree is not subject to a state or trade secret
WWW URL
Impact factor Impact factor: 3.664
RIV identification code RIV/00216224:14740/13:00070181
Organization unit Central European Institute of Technology
Doi http://dx.doi.org/10.1103/PhysRevB.87.014117
UT WoS 000314223600001
Keywords in English THEORETICAL STRENGTH; HOMOGENEOUS CRYSTALS; STABILITY; PRINCIPLES; STRESS
Tags ok, rivok
Tags International impact, Reviewed
Changed by Changed by: prof. RNDr. Mojmír Šob, DrSc., učo 3971. Changed: 15/1/2014 16:00.
Abstract
This work demonstrates a simple but efficient way as to how to determine the existence of shear instabilities in ideal bcc crystals under uniaxial loading. The theoretical tensile strengths are derived from calculated values of the theoretical shear strength and their dependence on the superimposed normal stress. The presented procedure enables us to avoid complicated and time-consuming analyses of elastic stability of crystals. Results of first-principles simulations of coupled shear and tensile deformations for the two most frequent slip systems ({110} < 111 > and {112} < 111 >) in six ideal cubic crystals are used to evaluate the uniaxial tensile strengths in three low-index crystallographic directions (< 100 >, < 110 >, and < 111 >) by assuming a shear instability in the weakest shear system. While instabilities occurring under < 100 > tension are mostly related to the shear in the {112} plane, those occurring during loading in the other two directions are associated with {110} planes. The results are consistent with those predicted by available elastic analyses. The weakest tendency to fail by shear is predicted for uniaxial tension along < 100 >. This is consistent with the occurrence of {100} cleavage planes in bcc metals.
Links
ED1.1.00/02.0068, research and development projectName: CEITEC - central european institute of technology
LD12037, research and development projectName: Studium bimetalických magnetických klastrů a nanodrátů z prvních principů (Acronym: BIMETAL)
Investor: Ministry of Education, Youth and Sports of the CR
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