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Cleanly Removable and Degradable Bio‐Based Adhesive for Flexible Displays
Summary
Researchers developed a new bio-based adhesive for flexible displays that can be cleanly removed with UV light and then broken down into its original building blocks for recycling. Unlike conventional acrylic adhesives that leave residue and persist as non-degradable microplastics, this new material uses lipoic acid compounds that degrade with a simple green reducing agent. The technology could help reduce plastic waste from electronics by making display components easier to separate and recycle.
In advanced applications such as flexible displays, reusing components is essential for achieving sustainability. However, the removal of acrylic pressure-sensitive adhesives (PSAs), which bond these components, remains a major challenge due to residue formation and the non-degradable C─C backbone. Here, the development of new acrylic PSA alternatives for foldable displays is reported by introducing ultraviolet (UV)-triggered debondability, degradability through lipoic acid analogs, and a visible-light-curing process. PSAs composed of 60 mol% lipoic acid ethyl ester (LpEt) and 3 mol% UV-cross-linkable benzophenone-functionalized acrylic monomers exhibit viscoelastic properties comparable to those of conventional acrylic PSAs, while also enable clean removal from substrates after use. Following removal, the PSAs efficiently degrade into small molecular units in the presence of a green reductant or can be recovered as monomers under controlled conditions. This strategy offers a promising pathway toward sustainable PSAs, enables the recycling of valuable substrates from flexible display modules while simultaneously allows adhesive recovery, thus presents a viable alternative to conventional acrylic adhesives.
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