Thermoresponsive Shape-Memory Hydrogel Actuators Made by Phototriggered Click Chemistry
Date
2020Abstract
This article describes the design and synthesis of a new series of hydrogel
membranes composed of trialkyne derivatives of glycerol ethoxylate and
bisphenol A diazide (BA-diazide) or diazide-terminated PEG600 monomer via
a Cu(I)-catalyzed photoclick reaction. The water-swollen hydrogel membranes
display thermoresponsive actuation and their lower critical solution temperature
(LCST) values are determined by differential scanning calorimetry. Glycerol
ethoxylate moiety serves as the thermoresponsive component and hydrophilic
part, while the azide-based component acts as the hydrophobic comonomer
and most likely provides a critical hydrophobic/hydrophilic balance contributing
also to the significant mechanical strength of the membranes. These hydrogels
exhibit a reversible shape-memory effect in response to temperature through
a defined phase transition. The swelling and deswelling behavior of the
membranes are systematically examined. Due to the click nature of the reaction,
easy availability of azide and alkyne functional-monomers, and the polymer
architecture, the glass transition temperature (Tg) is easily controlled through
monomer design and crosslink density by varying the feed ratio of different
monomers. The mechanical properties of the membranes are studied by
universal tensile testing measurements. Moreover, the hydrogels show the ability
to absorb a dye and release it in a controlled manner by applying heat below and
above the LCST.