Rugged Island-Bridge Inorganic Electronics Mounted on Locally Strain-Isolated Substrates

Various strain isolation strategies that combine rigid and stretchable regions for stretchable electronics were recently proposed, but the vulnerability of inorganic materials to mechanical stress has emerged as a major impediment to their performance. We report a strain-isolation system that combin...

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Veröffentlicht in:ACS nano 2024-05, Vol.18 (20), p.13061-13072
Hauptverfasser: Lee, Dae Hwan, Yea, Junwoo, Ha, Jeongdae, Kim, Dohyun, Kim, Sungryong, Lee, Junwoo, Park, Jang-Ung, Park, Taiho, Jang, Kyung-In
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Sprache:eng
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Zusammenfassung:Various strain isolation strategies that combine rigid and stretchable regions for stretchable electronics were recently proposed, but the vulnerability of inorganic materials to mechanical stress has emerged as a major impediment to their performance. We report a strain-isolation system that combines heteropolymers with different elastic moduli (i.e., hybrid stretchable polymers) and utilize it to construct a rugged island-bridge inorganic electronics system. Two types of prepolymers were simultaneously cross-linked to form an interpenetrating polymer network at the rigid–stretchable interface, resulting in a hybrid stretchable polymer that exhibited efficient strain isolation and mechanical stability. The system, including stretchable micro-LEDs and microheaters, demonstrated consistent operation under external strain, suggesting that the rugged island-bridge inorganic electronics mounted on a locally strain-isolated substrate offer a promising solution for replacing conventional stretchable electronics, enabling devices with a variety of form factors.
ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.4c01759