User‐Interactive Thermotherapeutic Electronic Skin Based on Stretchable Thermochromic Strain Sensor

User‐Interactive Thermotherapeutic Electronic Skin Based on Stretchable Thermochromic Strain Sensor

User‐interactive electronic skin (e‐skin) with a distinguishable output has enormous potential for human–machine interfaces and healthcare applications. Despite advances in user‐interactive e‐skins, advances in visual user‐interactive therapeutic e‐skins remain rare. Here, a user‐interactive thermot...

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Bibliographic Details
Published in:Advanced science Vol. 7; no. 17; pp. 2001184 - n/a
Main Authors: Lee, Giwon, Bae, Geun Yeol, Son, Jong Hyun, Lee, Siyoung, Kim, Seong Won, Kim, Daegun, Lee, Seung Goo, Cho, Kilwon
Format: Journal Article
Language:English
Published: Germany John Wiley & Sons, Inc 01-09-2020
John Wiley and Sons Inc
Wiley
Subjects:
Color
Communication
Communications
Connective tissue
electronic skins
Heat
Hydrophilic surfaces
Hydrophobic surfaces
Microscopy
Polyethylene terephthalate
Sensors
silver nanowires
Skin
Spectrum analysis
strain sensors
thermochromic composites
Visualization
wrinkles
thermochromic composites
wrinkles
silver nanowires
strain sensors
electronic skins
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Summary:User‐interactive electronic skin (e‐skin) with a distinguishable output has enormous potential for human–machine interfaces and healthcare applications. Despite advances in user‐interactive e‐skins, advances in visual user‐interactive therapeutic e‐skins remain rare. Here, a user‐interactive thermotherapeutic device is reported that is fabricated by combining thermochromic composites and stretchable strain sensors consisting of strain‐responsive silver nanowire networks on surface energy‐patterned microwrinkles. Both the color and heat of the device are easily controlled through electrical resistance variation induced by applied mechanical strain. The resulting monolithic device exhibits substantial changes in optical reflectance and temperature with durability, rapid response, high stretchability, and linear sensitivity. The approach enables a low‐expertise route to fabricating dynamic interactive thermotherapeutic e‐skins that can be used to effectively rehabilitate injured connective tissues as well as to prevent skin burns by simultaneously accommodating stretching, providing heat, and exhibiting a color change. User‐interactive thermotherapeutic electronic skin (e‐skin) is fabricated by combining thermochromic composites and stretchable strain sensors consisting of strain‐responsive silver nanowire networks on surface energy‐patterned microwrinkles. Both the color and heat of the device are easily controlled through electrical resistance variation induced by external mechanical strain. This e‐skin can be applied to effectively rehabilitate a connective tissue injury, being avoided from skin burns.
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202001184