Coarse-grained modeling of polymers with end-on and side-on liquid crystal moieties: effect of architecture

TL;DR

This study develops a coarse-grained model to explore how different architectures of liquid crystal polymers affect their phase transitions and shape changes, providing insights for designing responsive materials.

Contribution

The paper introduces a new coarse-grained modeling approach that captures the effects of architecture on phase behavior and shape change in liquid crystal polymers.

Findings

End-on side-chain systems have higher LC to isotropic transition temperatures.

Well-organized mesophase structures form at low temperatures.

Polymer architecture influences reversible deformation behavior.

Abstract

Mesogens, which are typically stiff rodlike or disklike molecules, are able to self-organize into liquid crystal (LC) phases in a certain temperature range. Such mesogens, or LC groups, can be attached to polymer chains in various configurations including within the backbone (main-chain LC polymers) or at the ends of side-chains attached to the backbone in an end-on or side-on configuration (side-chain LC polymers or SCLCPs), which can display synergistic properties arising from both their LC and polymeric character. At lower temperatures, chain conformations may be significantly altered due to the mesoscale LC ordering, thus, when heating from the LC ordered state through the LC to isotropic phase transition, the chains return from a more stretched to a more random coil conformation. This can cause macroscopic shape changes, which depend significantly on the type of LC attachment and other architectural properties of the polymer. Here, to study the structure-property relationships for SCLCPs with a range of different architectures, we develop a coarse-grained model that includes torsional potentials along with LC interactions of a Gay--Berne form. We create systems of different side chain lengths, chain stiffnesses, and LC attachment types, and track their structural properties as a function of temperature. Our modeled systems indeed form a variety of well-organized mesophase structures at low temperatures, and we predict higher LC to isotropic transition temperatures for the end-on side-chain systems than for analogous side-on side-chain systems. Understanding these phase transitions and their dependence on polymer architecture can be useful in designing materials with reversible and controllable deformations.