数码产品
材料科学
纳米技术
软质材料
产量(工程)
柔性电子器件
热的
粘附
光电子学
转印
可伸缩电子设备
热传递
机制(生物学)
压力(语言学)
生物材料
纳米尺度
电子材料
传热
作者
Kyeong Min Song,Myung-Kun Chung,Jeehoon Jung,Jungjae Park,Min-Uk Kim,Jae-Young Yoo,Minsu Park,Geumbee Lee,Jeehyun Hong,Jun‐Bo Yoon,Yeon Sik Jung
标识
DOI:10.1038/s41467-026-70948-5
摘要
Seamless integration of soft electronics with biological tissues enables high-fidelity physiological sensing by maintaining intimate mechanical and thermal contact. However, transferring these devices onto highly curved and fragile surfaces remains challenging, as conventional methods often induce strain, thermal distortion, or tissue damage. To address these challenges, we introduce a deformation-decoupling, adhesion-switchable yield-stress fluid (DAYS-fluid) that enables non-invasive, damage-free transfer of soft electronics onto complex biological surfaces, including those with undercuts and negative curvature. DAYS-fluid undergoes a reversible solid-to-liquid transition at an ultra-low yield stress of 0.0253 kPa, far below the rupture pressure (~0.2 kPa) of extremely fragile biological substrates such as raw egg yolk. This low yield stress, combined with tunable viscosity, decouples fluid motion from embedded electronics, preserving structural integrity during transfer. A water-triggered adhesion-switching mechanism further reduces interfacial adhesion to near zero, enabling gentle detachment. We demonstrate high-fidelity thermal sensing on moving joints, without compromising device performance or tissue integrity.
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