From Fluorescence‐Transfer‐Lightening‐Printing‐Assisted Conductive Adhesive Nanocomposite Hydrogels toward Wearable Interactive Optical Information‐Electronic Strain Sensors

材料科学 自愈水凝胶 转印 纳米复合材料 胶粘剂 纳米技术 荧光 可穿戴计算机 导电体 可穿戴技术 电子皮肤 光电子学 复合材料 高分子化学 光学 计算机科学 物理 嵌入式系统 图层(电子)
作者
Gongmeiyue Su,Ni Wang,Yangkun Liu,Ruoyao Zhang,Zhao Li,Yulin Deng,Ben Zhong Tang
出处
期刊:Advanced Materials [Wiley]
卷期号:36 (25): e2400085-e2400085 被引量:74
标识
DOI:10.1002/adma.202400085
摘要

Abstract The interactive flexible device, which monitors the human motion in optical and electrical synergistic modes, has attracted growing attention recently. The incorporation of information attribute within the optical signal is deemed advantageous for improving the interactive efficiency. Therefore, the development of wearable optical information‐electronic strain sensors holds substantial promise, but integrating and synergizing various functions and realizing strain‐mediated information transformation keep challenging. Herein, an amylopectin (AP) modified nanoclay/polyacrylamide‐based nanocomposite (NC) hydrogel and an aggregation‐induced‐emission‐active ink are fabricated. Through the fluorescence‐transfer printing of the ink onto the hydrogel film in different strains with nested multiple symbolic information, a wearable interactive fluorescent information‐electronic strain sensor is developed. In the sensor, the nanoclay plays a synergistic “one‐stone‐three‐birds” role, contributing to “lightening” fluorescence (≈80 times emission intensity enhancement), ionic conductivity, and excellent stretchability (>1000%). The sensor has high biocompatibility, resilience (elastic recovery ratio: 97.8%), and strain sensitivity (gauge factor (GF): 10.9). Additionally, the AP endows the sensor with skin adhesiveness. The sensor can achieve electrical monitoring of human joint movements while displaying interactive fluorescent information transformation. This research poses an efficient strategy to develop multifunctional materials and provides a general platform for achieving next‐generation interactive devices with prospective applications in wearable devices, human‐machine interfaces, and artificial intelligence.
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