Litcius/Paper detail

A three-dimensionally architected electronic skin mimicking human mechanosensation

Zhi Yong Liu, Xiaonan Hu, Renheng Bo, Youzhou Yang, Xu Cheng, Wenbo Pang, Q. Liu, Yuejiao Wang, Shuheng Wang, Shiwei Xu, Zhangming Shen, Yihui Zhang

2024Science347 citationsDOI

Abstract

Human skin sensing of mechanical stimuli originates from transduction of mechanoreceptors that converts external forces into electrical signals. Although imitating the spatial distribution of those mechanoreceptors can enable developments of electronic skins capable of decoupled sensing of normal/shear forces and strains, it remains elusive. We report a three-dimensionally (3D) architected electronic skin (denoted as 3DAE-Skin) with force and strain sensing components arranged in a 3D layout that mimics that of Merkel cells and Ruffini endings in human skin. This 3DAE-Skin shows excellent decoupled sensing performances of normal force, shear force, and strain and enables development of a tactile system for simultaneous modulus/curvature measurements of an object through touch. Demonstrations include rapid modulus measurements of fruits, bread, and cake with various shapes and degrees of freshness.

Topics & Concepts

MechanosensationElectronic skinHuman skinShear forceCurvatureMechanoreceptorMaterials scienceNormal forceShear modulusModulusComputer scienceNanotechnologyPhysicsComposite materialNeuroscienceChemistryBiologyMechanicsSensory systemMathematicsGeometryReceptorIon channelGeneticsBiochemistryAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsInteractive and Immersive Displays