【摘 要】
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The evolution of membrane-type electronics has facilitated the development of stick-and-play systems,which confer diverse electrical functions to various planar or arbitrary curvilinear surfaces.The stick-and-play concept is based on the development of th
【机 构】
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School of Materials Science and Engineering,Gwangju Institute of Science and Technology (GIST),Gwang
论文部分内容阅读
The evolution of membrane-type electronics has facilitated the development of stick-and-play systems,which confer diverse electrical functions to various planar or arbitrary curvilinear surfaces.The stick-and-play concept is based on the development of thin electronic devices in a printable format and their subsequent transfer to target surfaces.The development of this technology requires control of the interfacial adhesion of the electronic prints for retrieval from a carrier and transfer to the target surface.First,we discuss the transfer printing for membrane-type electronics,starting from an overview of materials available for flexible substrates,transfer printing of electronic prints for retrieval,and assembly for further integration.Second,we explain the stick-and-play concept based on fabricated membrane-type electronics;“stick” and “play” refer to the transfer of electronic devices and the performance of their electronic functions,respectively.In particular,we broadly survey various methods based on micro/nanostructures,including gecko-inspired,interlocking,cephalopod-sucker-inspired,and cilia structures,which can be employed to stick-and-play systems for enhancing interfacial adhesion with complex target surfaces under dynamic and wet conditions.Finally,we highlight the stick-and-play system application of micro/nanostructures for skin-attachable biomedical electronics,e-textiles,and environmental monitoring electronics.
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