Transparent soft materials are widely used in applications ranging from packaging to flexible displays, wearable devices, and optical lenses. Nevertheless, soft materials are susceptible to mechanical damage, leading to functional failure and premature disposal. Herein, a transparent self-healing elastomer that is able to repair the polymer network via exchange reactions of dynamic disulfide bonds is introduced. Due to its self-healing ability, the mechanical properties of the elastomer can be recovered as well as its transparency after multiple cycles of abrasion and healing. The self-healing polymer is fabricated into 3D structures by folding or modular origami assembly of planar self-healing polymer sheets. The 3D polymer objects are employed as storage containers of solid and liquid substances, reactors for photopolymerization, and cuvettes for optical measurements (exhibiting superior properties to those of commercial cuvettes). These dynamic polymers show outstanding mechanical, optical, and recycling properties that could potentially be further adapted in adaptive smart packaging, reconfigurable materials, optical devices, and recycling of elastomers.
Keywords: elastomers; optical materials; polyurethane; self-healing; shape-programming polymers.
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