材料科学
制作
纤维
平面的
电子线路
光电子学
流体学
纳米技术
可扩展性
电子工程
计算机科学
CMOS芯片
多模光纤
稳健性(进化)
柔性电子器件
晶体管
集成电路
可穿戴技术
光子晶体光纤
作者
Jiongke Jin,Mei Zou,Deyu Liu,Haoxuan Ma,Yingying Zhang
标识
DOI:10.1038/s41467-026-69640-5
摘要
Fiber represents a transformative architecture for next-generation wearable electronics, owing to its intrinsic flexibility, spatial compactness, and manufacturing adaptability. However, the geometric incompatibility between curved fiber substrates and conventional planar photolithography/printing techniques has hindered the fabrication of high-density microcircuits on fibers. Here, we introduce a shrinkage-transfer-assisted printing (STAP) strategy that bridges 2D planar circuit fabrication and 1D fiber device construction by shrinking fluidic eutectic gallium-indium (EGaIn) circuits and transferring them onto curved fiber surfaces. This approach achieves a shrinkage ratio of up to 80% with a resolution of 60 μm via scalable screen printing, and employs a capillary-driven transfer process to realize 360° conformal coverage of circuits on fibers. The resulting fiber devices exhibit mechanical robustness over 16,000 bending cycles. As a proof of concept, we demonstrate an electroluminescent fiber display system with individually addressable pixels. This work provides a versatile strategy for manufacturing microcircuits on curved fiber surfaces, opening a route toward scalable and multifunctional fiber electronics.
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