In this study, atomistic finite deformation calculations employing the Embedded Atom Method show three items of interest related to continuum field theory. First, a spatial size scale effect on the yield stress is found. In these calculations, mechanical yield point occurred from dislocation initiation at the edge of the numerical specimens. The spatial size scale continued to affect the plastic response up to strains of 30 percent in simple shear for nickel oriented at 〈011〉. The second point is related to the continuum mechanics observation about oscillating global shear stress under simple shear conditions is shown to dampen as the spatial size scale increases. As the spatial length scale increases, the continuum rotational effect coupled with the increase in dislocation population reduces the oscillatory behavior. This confirms the notion proposed by Bammann and Aifantis (1987) in that when more dislocations are initiated with different orientations of the Burger’s vectors then the oscillations decrease. Finally, a length scale bridging idea is proposed by relating a continuum single degree of freedom loss coefficient, which relates the plastic energy to the total strain energy, to varying sizes of blocks of atoms. This study illustrates the usefulness of employing the Embedded Atom Method to study mechanisms related to continuum mechanics quantities.

1.
Angelo
J. E.
,
Moody
N. R.
, and
Baskes
M. I.
,
1995
, “
Trapping of Hydrogen to Lattice Defects in Nickel
,”
J. Modelling Simul. Mater. Sci. Eng.
, Vol.
3
, pp.
289
307
.
2.
Bammann
D. J.
, and
Aifantis
B. C.
,
1987
, “
A Model for Finite Deformation Plasticity
,”
Acta Mechanica
, Vol.
69
, pp.
97
117
.
3.
Bammann, D.J., and Dawson, P.R., 1997, “Effects of Spatial Gradients in Hardening Evolution upon Strain Localization,” Physics and Mechanics of Finite Plastic and Viscoplastic Deformation, eds. A.S. Khan, pp. 9–10.
4.
Baskes
M. I.
,
Sha
X.
,
Angelo
J. E.
, and
Moody
N. R.
,
1997
, “
Comment: Trapping of Hydrogen to Lattice Defects in Nickel
,”
Modelling Simul. Mater. Sci. Eng.
, Vol.
5
, pp.
651
652
.
5.
Bourcier, R.J., Sniegowski, J.J., and Porter, V.L., 1996, “A Novel Method to Characterize the Elastic/Plastic Deformation Response of Thin Films,” SAND96-1794, Sandia National Laboratories Report, 1996.
6.
Brenner, D.W., 1996, “Chemical Dynamics and Bond-Order Potentials,” MRS Bulletin, pp. 36–41.
7.
Cheung
K. S.
, and
Yip
S.
,
1991
, “
Atomic Level Stress in Inhomogeneous System
,”
J. Appl. Phys., Communications
, Vol.
70
, No.
10
, pp.
5688
5690
.
8.
Cosserat, E. and Cosserat, F., 1909, Theorie des corps deformables, Herman, Paris, Fr.
9.
Daw
M. S.
and
Baskes
M. I.
,
1984
,
Phys. Rev.
, Vol.
B29
, p.
6443
6443
.
10.
Daw
M. S.
,
Foiles
S. M.
, and
Baskes
M. I.
,
1993
, “
The Embedded-Atom Method: A Review of Theory and Applications
,”
Materials Science Reports, A Review Journal
, Vol.
9
, No.
7–8
, pp.
251
310
.
11.
Fleck
N. A.
,
Muller
G. M.
,
Ashby
M. F.
, and
Hutchinson
J. W.
,
1994
, “
Strain Gradient Plasticity: Theory and Experiment
,”
Acta Metall. Mater.
, Vol.
42
, pp.
475
487
.
12.
Freidel
J.
,
1952
,
Phil. Mag.
, Vol.
43
, p.
153
153
.
13.
Hardy
R. J.
,
1982
, “
Formulas for Determining Local Properties in Molecular-Dynamics Simulations: Shock Waves
,”
J. Chem. Phys.
, Vol.
76
, p.
622
622
.
14.
Holian
B. L.
,
1994
, “
Large Scale Molecular Dynamics Simulations of Plastic Deformation
,”
Radiation Effects and Defects in Solids
, Vol.
129
, pp.
41
44
.
15.
Irving
J. H.
, and
Kirkwood
J. G.
,
1950
, “
The Statistical Mechanical Theory of Transport Processes. IV. The Equations of Hydrodynamics
,”
J. Chem. Phys.
, Vol.
18
, p.
817
817
.
16.
Johnson
G. C.
, and
Bammann
D. J.
,
1984
, “
A Discussion of Stress Rates in Finite Deformation Problems
,”
Int. J. Solids and Structures
, Vol.
20
, No.
8
, pp.
725
737
.
17.
Nagtegaal, J.C. and DeJong, J.E., 1982, “Some Aspects of Nonisotropic Work Hardening in Finite Strain Plasticity,” Plasticity Metals at Finite Deformation, eds., E.H. Lee and R.L. Mallett, p. 65.
18.
Rowlinson
J. S.
,
1993
, “
Thermodynamics of Inhomogeneous Systems
,”
Pure and Applied Chem.
, Vol.
65
, pp.
873
882
.
19.
Stoneham, M., Harding, J., and Harker, T., 1996, “The Shell Model and Interatomic Potentials for Ceramics,” MRS Bulletin, Feb. 1996, pp. 29–35.
20.
Stott
M. J.
, and
Zaremba
E.
,
1980
,
Phys. Rev.
,
B22
, p.
1564
1564
.
21.
Zhou
S. J.
,
Carlsson
A. E.
, and
Thomson
R.
,
1994
, “
Dislocation Core-Core Interaction and Peierls Stress in a Model Hexagonal Lattice
,”
Physical Reviews B, Third Series
, Vol.
49
, No.
10
, pp.
6451
6456
.
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