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Hollow-porous fibers for intrinsically thermally insulating textiles and wearable electronics with ultrahigh working sensitivity
- Source :
- Materials horizons. 8(3)
- Publication Year :
- 2021
-
Abstract
- Wearable smart devices should be flexible and functional to imitate the warmth and sensing functions of human skin or animal fur. Despite the recent great progress in wearable smart devices, it is still challenging to achieve the required multi-functionality. Here, stretchable hollow-porous fibers with self-warming ability are designed, and the properties of electrical heating, strain sensing, temperature sensing and pressure sensing are achieved. The hollow-porous TPU fiber possesses an ultra-high stretchability (1468%), and the textiles woven from the fibers present a splendid thermal insulation property (the absolute value difference in temperature |ΔT| = 68.5 and 44 °C at extreme temperatures of 115 and −40.0 °C). Importantly, after conductive filler decoration, the fiber-based strain sensor exhibits one of the highest reported gauge factor (2.3 × 106) towards 100% strain in 7200 working stretch–release cycles. A low detection limit of 0.5% strain is also achieved. Besides, the fibers can be heated to 40 °C in 18 s at a small voltage of 2 V as an electrical heater. The assembled thermal sensors can monitor the temperature from 30 to 90 °C in real time, and the fiber-based capacitive type pressure sensor exhibits good sensing performance under force from 1 to 25 N. The hollow-porous fiber based all-in-one integrated wearable systems illustrate promising prospects for next generation electronic skins to detect human motions and body temperature with thermal therapy and inherent self-warming ability.
- Subjects :
- Materials science
business.industry
Process Chemistry and Technology
Capacitive sensing
Textiles
Electric Conductivity
Pressure sensor
Wearable Electronic Devices
Mechanics of Materials
Gauge factor
Thermal insulation
Optoelectronics
Animals
Humans
General Materials Science
Fiber
Electrical and Electronic Engineering
Electronics
business
Electrical conductor
Porosity
Wearable technology
Voltage
Subjects
Details
- ISSN :
- 20516355
- Volume :
- 8
- Issue :
- 3
- Database :
- OpenAIRE
- Journal :
- Materials horizons
- Accession number :
- edsair.doi.dedup.....29933eba01a8012cc2c704188662d113