Manufacturing Technics for Fabric/Fiber-Based Triboelectric Nanogenerators: From Yarns to Micro-Nanofibers

Fan, Chonghui; Zhang, Yuxin; Liao, Shiqin; Zhao, Min; Lv, Pengfei; Wei, Qufu

doi:10.3390/nano12152703

Cited by 15 publications

(10 citation statements)

References 80 publications

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“…Additionally, researchers have developed this PVDF-TrFE nanofiber into an intelligent gait sensing pad which can be used for personal gait judgment without power supply, showing a great potential in medical health detection (Figure 5D). Lee et al 107 108 lateral sliding mode, 109 single electrode mode, 110 and freestanding triboelectric layer mode 111 ), converting force signals into power signals (Figure 5E). 99 The vertical contact-separation mode sensors and lateral sliding mode sensors are typically composed of a pair of frictional layers with opposite polarity and two electrodes.…”

Section: Flexible Capacitive Sensorsmentioning

confidence: 99%

“…The triboelectric sensors are novel devices proposed in recent years for energy harvesting and sensing purposes. They can operate in four basic modes (vertical contact-separation mode, lateral sliding mode, single electrode mode, and freestanding triboelectric layer mode), converting force signals into power signals (Figure E) . The vertical contact-separation mode sensors and lateral sliding mode sensors are typically composed of a pair of frictional layers with opposite polarity and two electrodes.…”

Section: Design Of Electrospun Flexible Biomechanical Sensorsmentioning

confidence: 99%

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Electrospun Micro/Nanofiber-Based Biomechanical Sensors

Li,

Zhang,

et al. 2023

ACS Appl. Polym. Mater.

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Electrospun micro/nanofibers have gained popularity recently for flexible biomechanical sensors because of their advantages of lightness, compatibility, breathability, mechanical deformability, and function integrability, etc., offering them unprecedented sensitivities and versatilities. With increasing advances in the digital era, existing electrospun flexible sensors are not capable of catering to the demands of multiscenario applications including wearable electronics, interactive interfaces, and real-time continuous health monitoring. To ease and expedite their developments, we thoroughly reviewed their latest progress regarding design, preparation, and optimization. First, a brief overview of the design approaches of electrospun flexible biomechanical sensors based on the working mechanism is highlighted. Then, two kinds of preparation strategies including direct electrospinning and post-treatment-assisted electrospinning are discussed in detail. Further, four means for optimizing the performance and endowing multifunctions to electrospun flexible biomechanical sensors are demonstrated in terms of processing. Accordingly, the challenges and the potential solutions related to this topic are addressed, providing a future direction for the next generation of electrospun flexible biomechanical sensors.

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Section: Flexible Capacitive Sensorsmentioning

confidence: 99%

Section: Design Of Electrospun Flexible Biomechanical Sensorsmentioning

confidence: 99%

Electrospun Micro/Nanofiber-Based Biomechanical Sensors

Li,

Zhang,

et al. 2023

ACS Appl. Polym. Mater.

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“…This high applied voltage during the electrospinning polarizes the dipole of PVDF. The spontaneous polarization further supports the electrical output of corresponding TENGs. − Electrospinning is the least expensive way to fabricate consistent and continuous micro- or nanofibers. , Owing to its advantageous properties including flexibility, light weight, breathability, higher specific surface area, huge accumulated surface charge density, and porosity, micro- or nanofibers hold great promise for creating a new triboelectric active layer. , Compared to conventional techniques, the electrospinning technique may easily alter the dipole moment of specific polymers by organizing them molecularly or modifying their crystal array to achieve higher electrical outputs. − Kim et al also found that the electrospun nanofibers tend to deliver enhanced power generation compared to casted films. The electrospun nanofiber’s network structure creates a greater surface area and higher roughness, which help to improve TENGs' electrical performance, whereas the casted film has a small and smoother uneven surface .…”

Section: Introductionmentioning

confidence: 99%

“…26−28 Electrospinning is the least expensive way to fabricate consistent and continuous microor nanofibers. 29,30 Owing to its advantageous properties including flexibility, light weight, breathability, higher specific surface area, huge accumulated surface charge density, and porosity, micro-or nanofibers hold great promise for creating a new triboelectric active layer. 31,32 Compared to conventional techniques, the electrospinning technique may easily alter the dipole moment of specific polymers by organizing them molecularly or modifying their crystal array to achieve higher electrical outputs.…”

Section: Introductionmentioning

confidence: 99%

Nickel-Oxide-Doped Polyvinylidene Fluoride Nanofiber-Based Flexible Triboelectric Nanogenerator for Energy Harvesting and Healthcare Monitoring Applications

Venkatesan,

Arun

2024

ACS Appl. Electron. Mater.

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Triboelectric nanogenerators (TENGs) are renowned for capturing large-scale unused energy from ambient surroundings. A sustainable TENG can meet future energy demands without contaminating our environment. In the present study, we have synthesized nickel oxide nanoparticles (NiO NPs) via the coprecipitation method. Further, NiO NPs were doped with poly(vinylidene fluoride) (PVDF) (0 to 9 wt % w.r.t. PVDF concentration) to prepare the PVDF-NiO electrospun nanofibrous mat. The output efficiency was calculated in terms of open-circuit voltage (V oc ) and short-circuit current (I sc ). NiO-doped PVDF and thermoplastic polyurethane (TPU)-based TENG generated enhanced performance compared to the pristine PVDF (P-Ni-0)/TPU-based TENG. Among the six combinations of samples fabricated, 7 wt % of NiO-doped PVDF (P-Ni-7)/TPU-based TENG generated the utmost voltage of 252 V, which is almost 22-fold higher than the P-Ni-0/TPU triboelectric pair generated voltage (11.5 V). Similarly, the maximum current achieved was 7.3 μA, which is almost a 9-fold enhancement over the P-Ni-0/TPU triboelectric pair (0.8 μA). The power density of the optimized TENG ((P-Ni-7)/TPU) was 0.86 mW/m 2 , and it was directly used to light up 15 LEDs. Furthermore, a flexible and self-powered P-Ni-7/ TPU-based TENG device was demonstrated for real-time biomechanical motion measurements. Overall, this work disclosed a facile technique for doping NiO NPs into a PVDF matrix, and the fabricated TENG demonstrated efficiency when used for mechanical energy harvesting and sustainable power-supplying systems for miniaturized wearable electronic devices.

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“…T-TENGs can harvest large amounts of energy based on the movements of the human body in daily life, such as arm waving, walking, running, and arm and knee bending. [12][13][14][15] Previous studies have indicated that T-TENGs can be coated with polyvinylidene uoride (PVDF), PTFE, and polydimethylsiloxane (PDMS) to increase the frictional surface area. [16][17][18][19][20][21][22][23][24][25][26] Moreover, a high electrical output has been achieved using metals with hard properties as friction materials, for example, Au, Ag, and Cu.…”

Section: Introductionmentioning

confidence: 99%