Experimental and Theoretical Studies of the Molecular Motions in Polymer Crazing. 1. Tube Model

Han, Hye-Jin; McLeish, Tom; Duckett, R. A.; Ward, N. J.; Johnson, A. F.; Donald, Athene M.; Butler, Michael F.

doi:10.1021/ma961896o

Cited by 18 publications

(16 citation statements)

References 15 publications

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“…11 The different crazing regimes suggested by Kramer could clearly be observed in polymers of different molar mass, and a simple model based on stress-accelerated disentanglement was able to account for the dependence of crazing stress on molar mass in the disentanglement regime consistently with other studies. 24 These developments provide a valuable starting point when addressing the issue of dispersity.…”

Section: Introductionsupporting

confidence: 57%

“…Synthesis of small quantities of narrow molar mass distributions ( M̅ w / M̅ n ≤ 1.12) and miniaturization of solid-state tests enabled De Focatiis et al to study craze initiation in PS over a wide range of molar mass, between 68 and 967 kDa . The different crazing regimes suggested by Kramer could clearly be observed in polymers of different molar mass, and a simple model based on stress-accelerated disentanglement was able to account for the dependence of crazing stress on molar mass in the disentanglement regime consistently with other studies . These developments provide a valuable starting point when addressing the issue of dispersity.…”

Section: Introductionmentioning

confidence: 65%

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The Roles of Blending and of Molecular Weight Distribution on Craze Initiation

2017

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Craze initiation stress was measured in three-point bending isochronal creep tests on a series of entangled bimodal blends of polystyrenes of narrow dispersity, on three polystyrenes of broad dispersity, and on four blends of polystyrenes of broad dispersity. Crazing stress was found to increase rapidly with small additions of the higher molar mass component, quickly reaching a plateau. A simple model based on the weighted addition of the crazing stress contributions of the individual weight fractions obtained from an established piecewise linear crazing law was able to predict the crazing stress accurately in the bimodal blends using a power law exponent of 2.59 (90% CI [1.75–17.34]). In broad dispersity systems, in particular where short unentangled chains dilute the polymer, it was found necessary to modify the model using dynamic tube dilution theory. Dilution leads to a change in the entanglement length and hence in the molar mass at which transitions to disentanglement and chain scission crazing occur. With the improved model, crazing stress could be predicted even for the broad dispersity polymers with wide and bimodal distributions. This represents an opportunity for the molecular design of polymers by blending to achieve improved resistance to craze initiation.

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Section: Introductionsupporting

confidence: 57%

Section: Introductionmentioning

confidence: 65%

The Roles of Blending and of Molecular Weight Distribution on Craze Initiation

2017

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“…Note that chain pullout may be important close to the glass transition where Λ often rises . This effect has been included in tube-models of disentanglement during crazing. , …”

Section: Discussionmentioning

confidence: 99%

“…4 This effect has been included in tube-models of disentanglement during crazing. 50,60 Macromolecules Our simulations have used a very simple bead−spring model but show strikingly universal behavior over a range of chain stiffnesses that change the entanglement density by a factor of 3. This suggests that the results may apply to a range of experimental systems.…”

Section: Discussionmentioning

confidence: 99%

Entanglements in Glassy Polymer Crazing: Cross-Links or Tubes?

Tzoumanekas

Anogiannakis

et al. 2016

Macromolecules

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Models of the mechanical response of glassy polymers commonly assume that entanglements inherited from the melt act like chemical cross-links. The predictions from these network models and the physical picture they are based on are tested by following the evolution of topological constraints in simulations of model polymer glasses. The same behavior is observed for polymers with entanglement lengths N e that vary by a factor of 3. A prediction for the craze extension ratio Λ based on the network model describes trends with N e , but polymers do not have the taut configurations it assumes. There is also no evidence of the predicted geometrically necessary entanglement loss. While the number of entanglements remains constant, the identity of the chains forming constraints changes. The same relation between the amount of entanglement exchange and nonaffine displacement of monomers is found for crazing and thermal diffusion in end-constrained melts. In both cases, about 1/ 3 of the constraints change when monomers move by the tube radius. The results show that chains in deformed glassy polymers are constrained by their rheological tubes rather than by entanglements that act like discrete cross-links.

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“…The numerical simulation of crazing has been undertaken at various length scales. At the mo-lecular level, Han et al (1998) developed a model to describe the strain rate eect on the surface energy and crazing mechanisms in fairly low molecular weight polymers. On a somewhat larger scale of observation, Sha et al (1997) used a spring network model to explicitly model the ®brils in the craze.…”

Section: Introductionmentioning

confidence: 99%

Modeling of crazing using a cohesive surface methodology

Tijssens

Giessen

Sluys

2000

Mechanics of Materials

119

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A novel cohesive surface model for crazing in polymers is developed. The model incorporates the initiation, growth and breakdown of crazes based on micromechanical considerations. The initiation of crazes is controlled by the stress state, in particular by the hydrostatic stress and cohesive surface normal traction. The widening of a craze is based on a rate-dependent viscoplastic formulation and failure of the craze occurs when the ®brils reach a material-dependent maximum extension. Crazing is simulated using a high density of cohesive surfaces immersed in the continuum. The ®nite element method is used to discretize both cohesive surfaces and continuum separately. The capabilities of the method to describe multiple crazing is demonstrated with an example.

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Experimental and Theoretical Studies of the Molecular Motions in Polymer Crazing. 1. Tube Model

Cited by 18 publications

References 15 publications

The Roles of Blending and of Molecular Weight Distribution on Craze Initiation

The Roles of Blending and of Molecular Weight Distribution on Craze Initiation

Entanglements in Glassy Polymer Crazing: Cross-Links or Tubes?

Modeling of crazing using a cohesive surface methodology

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