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E‐Skin Tactile Sensor Matrix Pixelated by Position‐Registered Conductive Microparticles Creating Pressure‐Sensitive Selectors
Author(s) -
You Insang,
Choi SongEe,
Hwang Hyejin,
Han Sang Woo,
Kim Jin Woong,
Jeong Unyong
Publication year - 2018
Publication title -
advanced functional materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 6.069
H-Index - 322
eISSN - 1616-3028
pISSN - 1616-301X
DOI - 10.1002/adfm.201801858
Subject(s) - electronic skin , materials science , tactile sensor , pressure sensor , optoelectronics , electrical conductor , active matrix , pixel , electrode , flexibility (engineering) , matrix (chemical analysis) , schottky barrier , electrode array , biomedical engineering , acoustics , nanotechnology , computer science , electrical engineering , voltage , artificial intelligence , mechanical engineering , engineering , composite material , diode , chemistry , mathematics , robot , layer (electronics) , statistics , physics , thin film transistor
Electronic skin (E‐skin) imitates human skin by converting external stimuli into electrical signals. E‐skin requires high flexibility and a high level of device integration. Unlike conventional E‐skin creation methods, a highly sensitive pressure sensor matrix (100 pixels cm −2 ) made of position‐registered elastic conductive microparticles (MPs) is created. The MPs form a Schottky junction with the bottom electrode and the current through the junction is sensitive to external pressure, forming a simple one‐selector two‐terminal device array. The Schottky junction eliminates the electrical cross talks between the sensor pixels consisting of 64 MPs in each. The flexible pressure sensor matrix is used as an artificial fingertip for Braille reading and as an electronic scale based on detailed force distribution. This work opens up the possibility that assembled MPs, which have been a long‐standing research topic in academia, can be used to make practical electronic devices.