Přístupnostní navigace
E-application
Search Search Close
Publication detail
ČERNÝ, M. POKLUDA, J.
Original Title
The theoretical tensile strength of fcc crystals predicted from shear strength calculations
Type
journal article in Web of Science
Language
English
Original Abstract
This work presents a simple way how to estimate the uniaxial tensile strength on the basis of the theoretical shear strength calculations taking its dependence on a superimposed normal stress into account. The presented procedure enables us to avoid complicated and time-consuming analyses of elastic stability of crystals under tensile loading. The atomistic simulations of coupled shear and tensile deformations in cubic crystals are performed using first principles computational code based on pseudo-potentials and plane wave basis set. Six fcc crystals are subjected to shear deformations in convenient slip systems and a special relaxation procedure controls the stress tensor. Obtained dependence of the ideal shear strength on the normal tensile stress seems to be almost linearly decreasing for all investigated crystals. Taking these results into account, the uniaxial tensile strength values in three crystallographic directions were evaluated by assuming a collapse of the weakest shear system. Calculated strengths for <100> and <111> loading were found to be mostly lower than previously calculated tearing stresses related to tensile instability but rather close to those obtained by means of the shear instability analysis. On the other hand, the strengths for <110> almost match the tearing stresses.
Keywords
Theoretical strength, ab initio calculations, shear strength, fcc crystals
Authors
ČERNÝ, M.; POKLUDA, J.
RIV year
2009
Released
13. 3. 2009
ISBN
0953-8984
Periodical
Journal of Physics: Condensed Matter
Year of study
21
Number
14
State
United Kingdom of Great Britain and Northern Ireland
Pages from
145406
Pages to
Pages count
5
BibTex
@article{BUT48475, author="Miroslav {Černý} and Jaroslav {Pokluda}", title="The theoretical tensile strength of fcc crystals predicted from shear strength calculations", journal="Journal of Physics: Condensed Matter", year="2009", volume="21", number="14", pages="145406--145406", issn="0953-8984" }