Fiber/Fabric‐Based Piezoelectric and Triboelectric Nanogenerators for Flexible/Stretchable and Wearable Electronics and Artificial Intelligence

Dong, Kai; Xiao, Peng; Wang, Zhong Lin

doi:10.1002/adma.201902549

Cited by 865 publications

(632 citation statements)

References 312 publications

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“…[ 18 ] However, the recently reported fiber (yarn)‐shaped TENG usually has a short length, hefty diameter, and uneven fineness, which are inappropriate for fabric processing technology and directly affect the efficiency of weaving and fabric styles. [ 19 ] Furthermore, the research on F‐TENG which has special functionalities such as flame‐retardant performance, noise‐reduction ability, and better permeability is still lacking. Therefore, manipulation of the yarn spinning protocol to obtain yarns with even fineness and small diameter as well as design of fabric structure will be very significant for functional F‐TENGs.…”

Section: Figurementioning

confidence: 99%

A Machine‐Fabricated 3D Honeycomb‐Structured Flame‐Retardant Triboelectric Fabric for Fire Escape and Rescue

et al. 2020

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Fire disaster is one of the most common hazards that threaten public safety and social development: how to improve the fire escape and rescue capacity remains a huge challenge. Here, a 3D honeycomb‐structured woven fabric triboelectric nanogenerator (F‐TENG) based on a flame‐retardant wrapping yarn is developed. The wrapping yarn is fabricated through a continuous hollow spindle fancy twister technology, which is compatible with traditional textile production processes. The resulting 3D F‐TENG can be used in smart carpets as a self‐powered escape and rescue system that can precisely locate the survivor position and point out the escape route to timely assist victim search and rescuing. As interior decoration, the unique design of the honeycomb weaving structure endows the F‐TENG fabric with an excellent noise‐reduction ability. In addition, combining with its good machine washability, air permeability, flame‐retardency, durability, and repeatability features, the 3D F‐TENG may have great potential applications in fire rescue and wearable sensors as well as smart home decoration.

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Section: Figurementioning

confidence: 99%

A Machine‐Fabricated 3D Honeycomb‐Structured Flame‐Retardant Triboelectric Fabric for Fire Escape and Rescue

et al. 2020

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“…[2] In contrast, porous and breathable fabric electronics can be worn for a long time without causing skin discomfort. Accordingly, supercapacitors, [3] batteries, [4] triboelectric nanogenerators, [5] smart textiles, [6] and heaters [7] have been developed based on conductive fibers or conductive textiles.However, most conductive fibers are based on the transmission of electrons. Electron-conductive solid fibers prepared by doping conductive materials into fibers may significantly change the Young's moduli and reduce their stretchability and transparency.…”

mentioning

confidence: 99%

Mechanically and Electronically Robust Transparent Organohydrogel Fibers

et al. 2020

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Stretchable conductive fibers are key elements for next‐generation flexible electronics. Most existing conductive fibers are electron‐based, opaque, relatively rigid, and show a significant increase in resistance during stretching. Accordingly, soft, stretchable, and transparent ion‐conductive hydrogel fibers have attracted significant attention. However, hydrogel fibers are difficult to manufacture and easy to dry and freeze, which significantly hinders their wide range of applications. Herein, organohydrogel fibers are designed to address these challenges. First, a newly designed hybrid crosslinking strategy continuously wet‐spins hydrogel fibers, which are transformed into organohydrogel fibers by simple solvent replacement. The organohydrogel fibers show excellent antifreezing (< ‐80 °C) capability, stability (>5 months), transparency, and stretchability. The predominantly covalently crosslinked network ensures the fibers have a high dynamic mechanical stability with negligible hysteresis and creep, from which previous conductive fibers usually suffer. Accordingly, strain sensors made from the organohydrogel fibers accurately capture high‐frequency (4 Hz) and high‐speed (24 cm s−1) motion and exhibit little drift for 1000 stretch–release cycles, and are powerful for detecting rapid cyclic motions such as engine valves and are difficult to reach by previously reported conductive fibers. The organohydrogel fibers also demonstrate potential as wearable anisotropic sensors, data gloves, soft electrodes, and optical fibers.

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“…[11][12][13] Recently, soft, and skin-integrated electronics, sometime also known as "epidermal electronics" have been of great interest due to their flexibility, stretchability, and lightweight. [14][15][16][17] In the past several years, integration of functional materials into a flexible platform has become a hot research topic. [18][19][20][21] Owning to the advances in materials science and mechanics, construction of piezoelectric materials in flexible and stretchable formats provides the foundations for numerous applications in wearable and implantable systems.…”

Section: Flexible Pengmentioning

confidence: 99%

Recent progress on flexible nanogenerators toward self‐powered systems

Liu

Wang

Zhao

et al. 2020

InfoMat

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The advances in wearable/flexible electronics have triggered tremendous demands for flexible power sources, where flexible nanogenerators, capable of converting mechanical energy into electricity, demonstrate its great potential. Here, recent progress on flexible nanogenerators for mechanical energy harvesting toward self‐powered systems, including flexible piezoelectric and triboelectric nanogenerator, is reviewed. The emphasis is mainly on the basic working principle, the newly developed materials and structural design as well as associated typical applications for energy harvesting, sensing, and self‐powered systems. In addition, the progress of flexible hybrid nanogenerator in terms of its applications is also highlighted. Finally, the challenges and future perspectives toward flexible self‐powered systems are reviewed.

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Fiber/Fabric‐Based Piezoelectric and Triboelectric Nanogenerators for Flexible/Stretchable and Wearable Electronics and Artificial Intelligence

Cited by 865 publications

References 312 publications

A Machine‐Fabricated 3D Honeycomb‐Structured Flame‐Retardant Triboelectric Fabric for Fire Escape and Rescue

A Machine‐Fabricated 3D Honeycomb‐Structured Flame‐Retardant Triboelectric Fabric for Fire Escape and Rescue

Mechanically and Electronically Robust Transparent Organohydrogel Fibers

Recent progress on flexible nanogenerators toward self‐powered systems

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