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Three-Dimensional Printed Bimodal Electronic Skin with High Resolution and Breathability for Hair Growth

Shengbo Sang, Zhen Pei, Fan Zhang, Chao Ji, Qiang Li, Jianlong Ji, Kun Yang, Qiang Zhang

2022ACS Applied Materials & Interfaces25 citationsDOI

Abstract

People with neurological deficits face difficulties perceiving their surroundings, resulting in an urgent need for wearable electronic skin (e-skin) that can monitor external stimuli and temperature changes. However, the monolithic structure of e-skin is not conducive to breathability and hinders hair growth, limiting its wearing comfort. In this work, we prepared fully three-dimensional (3D) printed e-skin that allowed hair penetration and growth. This e-skin also achieved simultaneous pressure and temperature detection and a high tactile resolution of 100 cm–2, which is close to that of human fingertips. The temperature sensor maintained linear measurements within 10–60 °C. The pore microstructure prepared by a sacrificial template method helped the pressure-sensing unit achieve a high sensitivity of 0.213 kPa–1. Considering the distribution of human hair, the design of the main structure of the e-skin was studied to realize hair penetration and growth. High-performance pressure-sensitive inks and transparent flexible substrate inks for 3D printing were developed, and e-skins combining these functions were realized through multimaterial in situ 3D printing with high accuracy and high consistency. The temperature and pressure sensors separately performed simultaneous detection without interference, and the tactile sensor array accurately identified stimuli at different locations.

Topics & Concepts

Materials scienceHigh resolutionPenetration (warfare)Substrate (aquarium)Human skinOptoelectronics3d printedPressure sensorElectronic skinBiomedical engineeringInkwellNanotechnologyAcousticsComposite materialMechanical engineeringPhysicsEngineeringOperations researchMedicineRemote sensingGeologyBiologyOceanographyGeneticsAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsNanomaterials and Printing Technologies
Three-Dimensional Printed Bimodal Electronic Skin with High Resolution and Breathability for Hair Growth | Litcius