One group of models proposed for characterizing the mechanical response of glassy polymers is based on a structure that resembles finite plasticity. In most cases, a constitutive equation for stress is proposed, which depends on the elastic deformation gradient, supplemented by a flow rule for the plastic deformation, which depends on the “over stress.” The over stress is a properly invariant difference between the stress and the back stress (equilibrium stress). The back stress represents conditions under which relaxation events should stop and the material should be able to carry an applied load indefinitely without a need to change the strain. Questions that arise in using these models are whether such equilibrium stresses exist, how can they be evaluated, and what experiments can be used to characterize the flow rule. One challenge in accurately evaluating the locus of equilibrium conditions is the fact that the relaxation process substantially slow down around these points, and, therefore, a method that does not directly require being at the equilibrium is desirable. Focusing on shear, a thermodynamic theory for characterizing the response of glassy polymers, similar to models currently used for this purpose, is developed, and using this model it is shown that one can set up a method to calculate the plastic strain rate. This method is based on evaluating the slope of stress-strain response under conditions of similar elastic and plastic strain, but different strain rates. Since the equilibrium stress occurs when the plastic strain rate goes to zero, the evaluated plastic strain rates allow evaluation of the needed information for developing the flow rule and obtaining the back stress. This method is used to evaluate the plastic strain rate and back stress at room temperature for polycarbonate. The evaluated results match well with results obtained by direct probing of the equilibrium stress, in which one searches for points at which the stress remains constant at a constant strain over long durations. The method proposed looks promising in evaluating the back stress of glassy polymers. The added advantage of this method is that it also provides a map of plastic strain rate and tangent modulus over a large range of loading conditions.

1.
Argon
,
A. S.
, 1975, “
Plastic Deformation in Glassy Polymers
,” in
Polymer Materials: Relationship Between Structure and Mechanical Behavior
,
American Society for Materials
, Metals Park, OH, pp.
411
486
.
2.
Argon
,
A. S.
, and
Bessonov
,
M. I.
, 1977, “
Plastic Flow in Glassy Polymers
,”
Polym. Eng. Sci.
0032-3888,
17
(
3
), pp.
174
182
.
3.
Argon
,
A. S.
, and
Bessonov
,
M. I.
, 1977, “
Plastic Deformation in Polyimides, With New Implications on the Theory of Plastic Deformation of Glassy Polymers
,”
Philos. Mag.
0031-8086,
35
(
4
), pp.
917
933
.
4.
Boyce
,
M. C.
,
Parks
,
D. M.
, and
Argon
,
A. S.
, 1988, “
Large Inelastic Deformation of Glassy Polymers. Part I: Rate Dependent Constitutive Model
,”
Mech. Mater.
0167-6636,
7
, pp.
15
33
.
5.
Boyce
,
M. C.
,
Parks
,
D. M.
, and
Argon
,
A. S.
, 1989, “
Plastic Flow in Oriented Glassy Polymers
,”
Int. J. Plast.
0749-6419,
5
, pp.
593
615
.
6.
Boyce
,
M. C.
, and
Arruda
,
E. M.
, 1990, “
An Experimental and Analytical Investigation of the Large Strain Compressive and Tensile Response of Glassy Polymers
,”
Polym. Eng. Sci.
0032-3888,
30
(
20
), pp.
1288
1298
.
7.
Arruda
,
E. M.
, and
Boyce
,
M. C.
, 1993, “
Evolution of Plastic Anisotropy in Amorphous Polymers During Finite Stretch
,”
J. Colour Soc.
0588-5094,
9
, pp.
697
721
.
8.
Arruda
,
E. M.
, and
Boyce
,
M. C.
, 1993, “
Strain Rate and Temperature Dependence in Amorphous Polymers at Finite Strain
,”
ASME MD: Use of Plastics and Plastic Composites: Materials and Mechanical Issues
,
ASME
, New York, Vol.
46
, pp.
697
721
.
9.
Arruda
,
E. M.
,
Boyce
,
M. C.
, and
Quintus-Bosz
,
H.
, 1993, “
Effects of Initial Anisotropy on the Finite Strain Deformation Behavior of Glassy Polymers
,”
Int. J. Plast.
0749-6419,
9
, pp.
783
811
.
10.
Boyce
,
M. C.
,
Arruda
,
E. M.
, and
Jayachandran
,
R.
, 1994, “
The Large Strain Compression, Tension, and Simple Shear of Polycarbonate
,”
Polym. Eng. Sci.
0032-3888,
34
(
9
), pp.
716
725
.
11.
Boyce
,
M. C.
,
Arruda
,
E. M.
, and
Jayachandran
,
R.
, 1995, “
Effects of Strain Rate, Temperature and Thermomechanical Coupling on the Finite Strain Deformation of Glassy Polymers
,”
Mech. Mater.
0167-6636,
19
, pp.
193
212
.
12.
Hasan
,
O. A.
,
Boyce
,
M. C.
,
Li
,
X. S.
, and
Berko
,
S.
, 1995, “
Constitutive Model for the Nonlinear Viscoelastic Viscoplastic Behavior of Glassy Polymers
,”
Polym. Eng. Sci.
0032-3888,
35
(
4
), pp.
331
344
.
13.
Arruda
,
E. M.
,
Boyce
,
M. C.
, and
Jayachandran
,
R.
, 1995, “
Effects of Strain Rate, Temperature and Thermo-Mechanical Coupling on the Finite Strain Deformation of Glassy Polymers
,”
Mech. Mater.
0167-6636,
19
, p.
193
212
.
14.
Krempl
,
E.
, and
Ho
,
K.
, 1995, “
Overstress Model for Solid Polymer Deformation Behavior Applied to Nylon 66
,”
Polym. Eng. Sci.
0032-3888,
35
, pp.
310
316
.
15.
Krempl
,
E.
, and
Bordonaro
,
C. M.
, 2000, “
State Variable Model for High Strength Polymers
,”
ASTM Special Technical Publication
, pp.
118
137
.
16.
Krempl
,
E.
, and
Khan
,
F.
, 2003, “
Rate (Time)-Dependent Deformation Behavior: An Overview of Some Properties of Metals and Solid Polymers
,”
Int. J. Plast.
0749-6419,
19
, pp.
1069
1095
.
17.
Krempl
,
E.
, and
Khan
,
F.
, 2004, “
Pre-Necking and Post-Necking Relaxation and Creep Behavior of Polycarbonate: A Phenomenological Study
,”
Polym. Eng. Sci.
0032-3888,
44
, pp.
1783
1791
.
18.
Negahban
,
M.
, 1995, “
Preliminary Results on an Effort to Characterize Thermo-Mechanical Response of Amorphous Polymers in the Glass-Transition Range
,”
ASME MD/AMD: Mechanics of Plastics and Plastic Composites
, ASME, New York, MD-vol.
68
/AMD-vol. 215, pp.
133
152
.
19.
Neu
,
R. W.
,
Scott
,
D. T.
, and
Woodmansee
,
M. W.
, 2000, “
Measurement and Modeling of Back Stress at Intermediate to High Homologous Temperatures
,”
Int. J. Plast.
0749-6419,
16
, pp.
283
301
.
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