Polymerizable deep eutectic solvent-gels synthesized in situ under molecular engineering control exhibit excellent adhesion, freeze resistance, as well as stretching and humidity sensing capabilities.

Hydrogels generally do not adhere well to different substrates and freeze at sub-zero temperatures, limiting their application. In this study, the strategy of replacing water in hydrogels with deep eutectic solvents (DES) was used to address these challenges. Specifically, choline chloride (ChCl) as hydrogen bond acceptor, acrylic acid (AA) and itaconic acid (IA) as hydrogen bond donors and polymerizable monomers constitute PDES. Afterwards, PDES-gel (PG) was obtained by adding a thermal initiator to polymerize AA and IA in PDES. PG has the following characteristics, because PG is almost water-free, it has remarkable low-temperature tolerance without any phase change at -60 °C to 20 °C. Thanks to the carboxyl groups and chloride ions contained in PG, it can form non-covalent interactions such as hydrogen bonding and ionic interactions with different substrates, so PG can adhere to various substrate surfaces. Furthermore, the breaking elongation of the novelty PG was up to ca. 960 %, tensile strength ca. 1 MPa, outstanding transparency with an average light transmittance of about 95 % in the visible-light range. Ultimately, the novel PG exhibited certain capabilities for moisture detection and deformation sensing. The new PDES-gel material developed using PDES is expected to provide new ideas for the advancement of wearable devices. Copyright © 2024 Elsevier Inc. All rights reserved.

Citation

Changhang Zhang, Xiaoyu Li, Xinyu Wu, Mingkai Yan, Hailan Lian. Polymerizable deep eutectic solvent-gels synthesized in situ under molecular engineering control exhibit excellent adhesion, freeze resistance, as well as stretching and humidity sensing capabilities. Journal of colloid and interface science. 2025 Feb;679(Pt B):245-253

PMID: 39454256

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