Litcius/Paper detail

Unusual photo-tunable mechanical transformation of azobenzene terminated aliphatic polycarbonate

Chaoxian Chen, Yufan Ji, Haoming Li, Tianfu Song, Haifeng Yu

2025Nature Communications20 citationsDOIOpen Access PDF

Abstract

Human substance needsśś have been enriched by the development of smart-responsive materials possessing unique responsiveness and mechanical variability. However, acquiring these features in photoresponsive energy-driven elastomers is challengeable but highly desirable. Here, we report fabrication of physically-crosslinked elastomers based on an aliphatic polycarbonate terminated with one azobenzene derivative as the end group. Upon irradiation of UV light, the aliphatic polycarbonate shows unusual mechanical transformation from trans-azobenzene-rich elasticity to cis-azobenzene-rich plasticity, which is contrary to the photo-triggered mechanics of other azopolymers. This indicates that stronger interaction may be established between the terminated cis-azobenzenes and the benzene rings in the side chain of polymer, leading to a higher crosslinking density appeared in the cis-azobenzene-rich sample. This azobenzene-terminated polymer is an energy-driven elastomer, which has photo-switchable supramolecular interactions, showing photo-tunable mechanical properties (the half-life period of the cis-azobenzene is 16.9 h). More interestingly, the photoinduced mechanical change occurs at room temperature, enabling the aliphatic polycarbonate to behave as non-thermally switchable ultra-strong adhesive for different substrates, which is specifically suitable for smart dressings to promote wound healing. This switchable mechanical feature of elastomers may be a reference for smart elastomers towards advanced applications. The development of photoresponsive energy-driven elastomers with unique responsiveness and mechanical variability is challenging. Here, the authors describe elastomers based on reversible cis-trans isomerization transition of azobenzene terminated aliphatic polycarbonate, allowing mechanical transformation for smart photo/thermal switchable adhesion and wound healing as medical dressings.

Topics & Concepts

AzobenzenePolycarbonateMaterials scienceTransformation (genetics)Polymer chemistryPhotochemistryChemistryPolymerComposite materialGeneBiochemistryPolymer composites and self-healingPhotochromic and Fluorescence ChemistryAdvanced Materials and Mechanics
Unusual photo-tunable mechanical transformation of azobenzene terminated aliphatic polycarbonate | Litcius