Issue 43, 2012

Modelling elasticity and memory effects in liquid crystalline elastomers by molecular dynamics simulations

Abstract

We performed molecular dynamics simulations of a liquid crystal elastomer of side-chain architecture. The network is formed from a melt of 28 molecules each having a backbone of 100 hydrocarbon monomers, to which 50 side chains are attached in a syndiotactic way. Crosslinking is performed in the smectic A phase. We observe an increase of the smectic–isotropic phase transition temperature of about 5 degrees as compared to the uncrosslinked melt. Memory effects in liquid crystalline order and in sample shape are well reproduced when the elastomer is driven through the smectic–isotropic transition. Above this transition, in the isotropic phase, the polydomain smectic phase is induced by a uniaxial load. Below the transition, in a monodomain smectic A phase, both experimentally observed effects of homogeneous director reorientation and stripe formation are reproduced when the sample is stretched along the director. When the load is applied perpendicularly to the director, the sample demonstrates reversible deformation with no change of liquid crystalline order, indicating elasticity of the two-dimensional network of polymer layers.

Graphical abstract: Modelling elasticity and memory effects in liquid crystalline elastomers by molecular dynamics simulations

Article information

Article type
Paper
Submitted
28 Jun 2012
Accepted
01 Aug 2012
First published
10 Sep 2012

Soft Matter, 2012,8, 11123-11134

Modelling elasticity and memory effects in liquid crystalline elastomers by molecular dynamics simulations

J. M. Ilnytskyi, M. Saphiannikova, D. Neher and M. P. Allen, Soft Matter, 2012, 8, 11123 DOI: 10.1039/C2SM26499D

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