Ultra-Stretchable Polymer Fibers Anchored with a Triple-Level Self-Assembled Conductive Network for Wide-Range Strain Detection
Zhong Zheng, Shuyi Song, Xun Chen, Xixing Li, Jing Li

TL;DR
This paper introduces a new ultra-stretchable sensor made from polymer fibers with a self-assembled conductive network for detecting strain over a wide range.
Contribution
A novel triple-level self-assembled conductive network is introduced to enhance stretchable sensor performance.
Findings
The sensor achieves a strain sensitivity (GF~2514) over 200% strain with fast response time (~150 ms).
The composite shows excellent durability over 1000 tensile cycles.
The design eliminates modulus mismatch between conductive materials and polymer substrates.
Abstract
Numerous strategies have been demonstrated to enhance the mechanical stretchability of electromechanical sensors for widespread applications in wearable electronics. However, ranging from composite to microstructural materials, their electromechanical sensing performances are usually vulnerable to large stretching deformations due to the low-ductility of the infilled conductive components and the modulus mismatch between the flexible polymer substrate and conductive fillers. Here, a novel design strategy is proposed to fabricate ultra-stretchable electromechanical composites constructed by a triple-level interaction conductive network (Tri-LICN) in buckled-TPU microfibers for strain sensors. The Tri-LICN is established by bridging one-dimensional cellulose nanocrystals (CNC) with zero-dimensional gold-nanoparticles (AuNPs) and two-dimensional MXene sheets using interface self-assembly…
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Taxonomy
TopicsAdvanced Sensor and Energy Harvesting Materials · Conducting polymers and applications · Dielectric materials and actuators
