Micromechanical characterization of the interphase layer in semi‐crystalline polyethylene

Ghazavizadeh, Akbar; Rutledge, Gregory C.; Atai, Ali Asghar; Ahzi, Saı̈d; Rémond, Yves; Soltani, Nasser

doi:10.1002/polb.23319

Cited by 25 publications

(29 citation statements)

References 57 publications

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“…undertook the first theoretical estimates of the thermal and mechanical properties of the "interlamellar phase" of semicrystalline linear PE by MC simulations using the PYS-UA FF or modified versions [367,368]. Using this interface MC (IMC) model and micromechanical homogenization approaches [369], it is possible to dissociate interfacial stiffness from that of the whole interlamellar region. The interphase thickness and conformational aspects of the chain segments in this region, together with the phase volumes, can be also deduced.…”

Section: Nature Of the Amorphous Region In Lamellar Polyethylenementioning

confidence: 99%

Predicting experimental results for polyethylene by computer simulation

Ramos

Vega

Martínez‐Salazar

2018

European Polymer Journal

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This feature article reviews several aspects of computational approaches to polyethylene melt and solid state properties in relation to existing experimental results. Based on 40 years of experience in the field, we offer a personal view of how computer simulations are helping to understand the physics of polyethylene as a model polymer. The first issue discussed is the molten state of polyethylene, including static and dynamic properties and entanglement features along with their impacts on rheological behaviour. We then examine the glass transition, crystallization process and solid state structure, including the interlamellar region. This is followed by brief descriptions of the latest advances in simulating mechanical properties and of the various methodologies used to simulate the physics of polyethylene. Throughout the manuscript, references are made to our own work and also to studies by many other authors that have nicely contributed to developments in simulating the physics of polyethylene in close agreement with experimental results.

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Section: Nature Of the Amorphous Region In Lamellar Polyethylenementioning

confidence: 99%

Predicting experimental results for polyethylene by computer simulation

Ramos

Vega

Martínez‐Salazar

2018

European Polymer Journal

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“…To gain insight into the complex behaviour of semicrystalline polymers, atomistic modelling is a useful numerical modelling tool that has been widely used in the literature [25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42][43][44]. Most of these works have been based on simplified and coarse-grained interaction models, such as the united atom (UA) interaction model.…”

Section: Introductionmentioning

confidence: 99%

All-atomic and coarse-grained molecular dynamics investigation of deformation in semi-crystalline lamellar polyethylene

Olsson

Veld

Andreasson

et al. 2018

Polymer

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In the present work we have performed classical molecular dynamics modelling to investigate the effects of different types of forcefields on the stress-strain and yielding behaviours in semi-crystalline lamellar stacked linear polyethylene. To this end, specifically the all-atomic optimized potential for liquid simulations (OPLS-AA) and the coarse-grained united-atom (UA) force-fields are used to simulate the yielding and tensile behaviour for the lamellar separation mode. Despite that the considered samples and their topologies are identical for both approaches, the results show that they predict widely different stress-strain and yielding behaviours. For all UA simulations we obtain oscillating stress-strain curves accompanied by repetitive chain transport to the amorphous region, along with substantial chain slip and crystal reorientation. For the OPLS-AA modelling primarily cavitation formation is observed, with small amounts of chain slip to reorient the crystal such that the chains align in the tensile direction. This force-field dependence is rooted in the lack of explicit H-H and C-H repulsion in the UA approach, which gives rise to underestimated ideal critical resolved shear stress. The computed critical resolved shear stress for the OPLS-AA approach is in good agreement with density functional theory calculations and the yielding mechanisms resemble those of the lamellar separation mode. The disparate energy and shear stress barriers for chain slip of the different models can be interpreted as differently predicted intrinsic activation rates for the mechanism, which ultimately are responsible for the observed diverse responses of the two modelling approaches.

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“…These force fields display different levels of atomic resolution and are commonly used for polymer modelling. Although there is a multitude of all-atom potentials available in the literature, the former was chosen for the present paper based on its common use, its simplicity and relatively low computational cost, while the latter was chosen because it has been used extensively for investigating the mechanical properties of amorphous and semi-crystalline polymers [32][33][34][35][36][37][38][39][40][41][42].…”

Section: Introductionmentioning

confidence: 99%