Thermally driven MEMS fiber-grippers

We investigate mechanical tangling for adhesion of microelectromechanical systems (MEMS) to unconventional carrier materials for assembly of highly porous, fiber-based electronics. Adhesion plays a crucial role in fabrication, but is a difficult task to realize even on continuous thin films of soft...

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Veröffentlicht in:Journal of micro-bio robotics 2022-12, Vol.18 (1-2), p.89-100
Hauptverfasser: Islam, Mohammad S., Challa, Sushmita, Yacin, M. H., Vankayala, Sruthi S., Song, Nathan, Wei, Danming, Beharic, Jasmin, Harnett, Cindy K.
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Sprache:eng
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Zusammenfassung:We investigate mechanical tangling for adhesion of microelectromechanical systems (MEMS) to unconventional carrier materials for assembly of highly porous, fiber-based electronics. Adhesion plays a crucial role in fabrication, but is a difficult task to realize even on continuous thin films of soft materials like silicone and polyimide. Adhesion becomes more challenging on discontinuous surfaces like fabric meshes, yet these substrates will expand the MEMS universe to new materials. Operations that are challenging on conventional circuit boards, like passage of electronic contacts and fluids from one side of a mesh to the other, are simpler with a mesh. In this work, microgripper arrays are realized by microfabrication and release of strained metal-oxide bilayers. This paper describes a process that wraps a MEMS gripper around a conductive fiber and reverses the process using electric current to open the gripper. The gripper’s electrical resistance serves as a self-temperature sensor over the 20–500 °C range. Beyond their potential for adhering MEMS to fabrics and to flexible/stretchable substrates that are incompatible with or resistant to adhesives, these microgrippers illustrate how MEMS-based microrobots might interact with small-scale (
ISSN:2194-6418
2194-6426
DOI:10.1007/s12213-023-00161-w