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Large-area, untethered, metamorphic, and omnidirectionally stretchable multiplexing self-powered triboelectric skins

Beibei Shao, Ming‐Han Lu, Tai-Chen Wu, Wei‐Chen Peng, Tien‐Yu Ko, Yung‐Chi Hsiao, Jiann‐Yeu Chen, Baoquan Sun, Ruiyuan Liu, Ying‐Chih Lai

2024Nature Communications144 citationsDOIOpen Access PDF

Abstract

Large-area metamorphic stretchable sensor networks are desirable in haptic sensing and next-generation electronics. Triboelectric nanogenerator-based self-powered tactile sensors in single-electrode mode constitute one of the best solutions with ideal attributes. However, their large-area multiplexing utilizations are restricted by severe misrecognition between sensing nodes and high-density internal circuits. Here, we provide an electrical signal shielding strategy delivering a large-area multiplexing self-powered untethered triboelectric electronic skin (UTE-skin) with an ultralow misrecognition rate (0.20%). An omnidirectionally stretchable carbon black-Ecoflex composite-based shielding layer is developed to effectively attenuate electrostatic interference from wirings, guaranteeing low-level noise in sensing matrices. UTE-skin operates reliably under 100% uniaxial, 100% biaxial, and 400% isotropic strains, achieving high-quality pressure imaging and multi-touch real-time visualization. Smart gloves for tactile recognition, intelligent insoles for gait analysis, and deformable human-machine interfaces are demonstrated. This work signifies a substantial breakthrough in haptic sensing, offering solutions for the previously challenging issue of large-area multiplexing sensing arrays.

Topics & Concepts

Triboelectric effectMultiplexingNanogeneratorHaptic technologyMaterials scienceElectromagnetic shieldingElectronicsComputer scienceStretchable electronicsElectronic skinElectrical engineeringNanotechnologyArtificial intelligenceTelecommunicationsVoltageEngineeringComposite materialAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsConducting polymers and applications