Stabilizing Metal Coating on Flexible Devices by Ultrathin Protein Nanofilms

材料科学 涂层 胶粘剂 聚合物 图层(电子) 聚合物基片 复合材料 基质(水族馆) 粘附 纳米技术 海洋学 地质学
作者
Yingying Zhang,Hao Ren,Changhong Linghu,Jiqing Zhang,Aiting Gao,Hao Su,Shuting Miao,Rongrong Qin,Bowen Hu,Xiao Jie Chen,Miaoran Deng,Yongchun Liu,Peng Yang
出处
期刊:Advanced Materials [Wiley]
卷期号:36 (52): e2412378-e2412378 被引量:17
标识
DOI:10.1002/adma.202412378
摘要

The significant modulus difference between a metal coating and a polymer substrate leads to interface mismatches, seriously affecting the stability of flexible devices. Therefore, enhancing the adhesion stability of a metal layer on an inert polymer substrate to prevent delamination becomes a key challenge. Herein, an ultrathin protein nanofilm (UPN), synthesized by disulfide-bond-reducing protein aggregation, is proposed as a strong adhesive layer to enhance adhesion between polymer substrate and metal coating. Unlike traditional biopolymer adhesives with micrometer-scale thicknesses, the UPN layer is minimized to nanometer/single-molecular scale. Such UPN thereby effectively enhances the interfacial adhesive strength and reduces the cohesion contribution in the entire adhesion system by directly connecting two interfaces with a nearly single-molecular thickness. Using UPN as the adhesive layer, a multifunctional metal coating could be reliably adhered on flexible polymer substrates by ion sputtering, delivering unprecedented adhesion stability even under repetitive mechanical deformation. Applications of this design include reversible transparency control, tension-responsive encryption, reusable optical sensing, and wearable capacitive touch sensors. This work highlights UPN's potential to create strong bonding strength between flexible polymers and metal coatings, offering a biocompatible solution with high surface activity and low cohesion, facilitating the development of hybrid devices with stable metal nano-coating.
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