posted on 2014-06-17, 13:14authored bySaurabh Puri, Anish RoyAnish Roy, Amit Acharya, Dennis Dimiduk
Size effects at initial yield (prior to stage II) of idealized micron-sized specimens are modeled within a continuum model of plasticity. Two different aspects are considered: specification of a density of dislocation sources that represent the emission of dislocation dipoles, and the presence of an initial, spatially inhomogeneous excess dislocation content. Discreteness of the source distribution appears to lead to a stochastic response in stress-strain curves, with the stochasticity diminishing as the number of sources increases. Variability in stress-strain response due to variations of source distribution is also shown. These size effects at initial yield are inferred to be due to physical length scales in dislocation mobility and the discrete description of sources that induce internal-stress-related effects, and not due to length-scale effects in the mean-field strain-hardening response (as represented through a constitutive equation).
History
School
Mechanical, Electrical and Manufacturing Engineering
Published in
JOURNAL OF MECHANICS OF MATERIALS AND STRUCTURES
Volume
4
Issue
9
Pages
1603 - 1618 (16)
Citation
PURI, S. ... et al, 2009. Modeling dislocation sources and size effects at initial yield in continuum plasticity. Journal of Mechanics of Materials and Structures, 4 (9), pp. 1603 - 1618.
Publisher
Mathematical Sciences Publishers
Version
VoR (Version of Record)
Publication date
2009
Notes
First published in Journal of Mechanics of Materials and Structures in 2009 vol 4 pt. 9, published by Mathematical Sciences Publishers.