Topological Constraint on Chain-Folding Structure of Semicrystalline Polymer

Wang, Kun

26 July 2019

No description available.

Polymers

Modélisation du comportement diffuso-mécanique d'un polymère semi-cristallin sous pression d'eau / Diffuso-Mechanical Modelling of Semicrystalline Polymer Under Water Pressure

Castro Lopez, William Camilo

11 September 2015

La compréhension des couplages hydro-mécaniques pouvant influencer le comportement mécanique d’un polymère semi-cristallin (PSC) sous forte pression d’eau est à l’origine de ce travail de recherche.Afin de décrire des phénomènes de diffusion d’eau et leurs impacts sur le comportement mécanique du matériau lors d’un chargement multiaxial, l’influence des caractéristiques microstructurales sur le comportement diffuso-mécanique du matériau a été considérée dans la modélisation. Un modèle de comportement mécanique permettant de rendre compte du phénomène de cavitation généré par d’importantes déformations en traction et de l’évolution du comportement mécanique macroscopique vis-à-vis de la pression de confinement est ainsi couplé à un modèle de sorption dépendant de l’état microstructural du matériau. Une représentation multiphasique à différentes échelles est considérée : à une échelle ‘macroscopique’, le polymère cavité sous pression d’eau est assimilé à un milieu poreux constitué d’une phase solide (PSC) et une phase fluide (l’eau saturant les pores). A l’échelle du polymère, le comportement viscoplastique du PSC est modélisé à partir de la thermodynamique des milieux poreux, appuyé dans une représentation mésoscopique de sa microstructure, où le réseau cristallin interagit avec l’amorphe libre.Le modèle couplé a été implémenté dans un code de calcul par Eléments Finis. Les résultats de simulation démontrent la potentialité du modèle proposé, notamment sa capacité à capter des phénomènes de couplage entre la microstructure du matériau, la diffusion d’espèces et l’état de contraintes et déformations locales du matériau, permettant ainsi d’explorer des voies de compréhension des observations expérimentales. / Comprehension of the hydro-mechanical coupling affecting the mechanical behavior of a semicrystalline polymer (SCP) under high water pressure was the motivation of this research work.In order to describe the water diffusion phenomenon and its impact on the mechanical behavior of the SCP when multiaxial stresses are applied, the effect of the microstructure on the diffuso-mechanical behavior of the polymer was considered for modeling. A constitutive model including void nucleation and growth induced by large strains, and a dependence of the macroscopic mechanical behavior on hydrostatic pressure, is then coupled with a sorption model depending on the microstructure of the polymer.A multiphase representation at two scales is considered: at a ‘macroscopic’ scale, the cavitated SCP under water pressure is considered to be a saturated porous medium with the SCP as the solid phase, and the water saturating the voids as the fluid phase.At a lower scale, the viscoplastic behavior of the SCP has been modeled from the thermodynamics of porous media based on a meso-scale representation of its microstructure with the crystalline lamellae interacting with the free amorphous.The coupled model was implemented into a finite elements code. The simulation results demonstrate the potential of the proposed model, in particular its capability to take into account coupling phenomena between the microstructure of the material, species diffusion and the local state of stresses and strains which contributes to the comprehension of experimental observations.

Polymère semicristallin

Couplage multi-physique

Semicrystalline polymer

Multiphysical coupling

Molecular Mechanics of Glassy And Semicrystalline Polymers

Razavi, Masoud

25 August 2020

No description available.

Polymers

Physics

polymer glasses

semicrystalline polymer

mechanical behavior

molecular mechanics

Structure and Dynamics in Novel Polyolefin and Their Blends for Sustainability

Kafle, Navin K.

02 August 2023

No description available.

Materials Science

Plastics

Physics

Polyolefins

Blends

Semicrystalline Polymer Blends

Sustainability

New Shape Memory Effects in Semicrystalline Polymeric Networks

Chung, Taekwoong

30 March 2009

No description available.

Polymers

shape memory polymers

semicrystalline polymer networks

two-way shape memory effects

Local Structure and Molecular Dynamics of Supramolecules And Semicrystalline Polymers As Investigated By Solid State NMR

Chen, Wei

07 June 2016

No description available.

Polymers

Supramolecule

Semicrystalline Polymer

Solid state NMR

polyethylene oxide

PEO

polyoxymethylene

POM

polylactide

PLA

A unified model of necking and shear banding in amorphous and semicrystalline polymers

Coates, Philip D., Sweeney, John, Caton-Rose, Philip D., Spares, Robert

January 2007

No / In tensile stretching, many polymers undergo strain localization. The geometrical form of the localization can take the form of either a shear band or an approximately symmetric neck. We present a constitutive model of the early stages of deformation that predicts which form the localization will take. The model consists of an Eyring process acting with a Gaussian network that is implemented numerically. A Levy-Mises flow rule associated with the Eyring process has a tendency to produce shear bands. A relatively stiff Gaussian network is used in a model of polycarbonate that ensures that most of the strain is taken up by the Eyring process, resulting in shear banding. In contrast, a relatively soft Gaussian network is used in a model of polyethylene, which takes up the greater part of the strain, resulting in a neck. The predictions are compared with experiments. For polyethylene, a two-Eyring-process model is introduced for better accuracy.

Mechanical properties

Olefin polymer

Numerical simulation

Finite element method

Gaussian network

Eyring model

Polyethylene

Polycarbonate

Semicrystalline polymer

Amorphous polymer