Recent Advances in Triboelectric Nanogenerators for Marine Exploitation

Zhang, Chuguo; Hao, Yijun; Yang, Jiayi; Su, Wei; Zhang, Hongke; Wang, Jie; Wang, Zhong Lin; Li, Xiuhan

doi:10.1002/aenm.202300387

Cited by 42 publications

(9 citation statements)

References 254 publications

(517 reference statements)

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“…TENG as having significant potential in the realms of personalized healthcare and mobile therapy [18,[58][59][60][61][62]. Moreover, the electrical signals generated by TENG have direct applications in the stimulation of biological cells, nerves, tissues, and organs for electrical stimulation (ES) therapy [62][63][64][65].…”

Section: Teng In Biomedical Fieldmentioning

confidence: 99%

Ultrasound-driven triboelectric and piezoelectric nanogenerators in biomedical application

Kao,

Hung,

Yang

et al. 2024

J. Phys. Energy

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Microelectronics play a crucial role in medical settings by monitoring physiological signals, treating illnesses, and enhancing human well-being. For implanted and wearable devices, a reliable and continuous energy source is essential. While conventional energy systems rely on batteries and external power connections, their drawbacks, including the need for frequent charging, limited battery lifespan, and the potential for reoperation, restrict their utility. This has spurred the exploration of self-sustaining, long-lasting power solutions. The ultrasound-driven nanogenerator, a promising energy source, harnesses biomechanical energy from activities like muscle movement, heartbeat, respiration, and gastric peristalsis. It converts this energy into electrical signals, enabling the detection of physiological and pathological markers, cardiac pacing, nerve stimulation, tissue repair, and weight management. In this review, we provide an overview of triboelectric (TENG) and piezoelectric (PENG) nanogenerator design with ultrasound and its applications in biomedicine, offering insights for the advancement of self-powered medical devices in the future. These devices hold potential for diverse applications, including wound treatment, nerve stimulation and regeneration, as well as charging batteries in implanted devices.

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Section: Teng In Biomedical Fieldmentioning

confidence: 99%

Ultrasound-driven triboelectric and piezoelectric nanogenerators in biomedical application

Kao,

Hung,

Yang

et al. 2024

J. Phys. Energy

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“…With the rapid development of artificial intelligence and fifth-generation mobile communication technology, human–machine interaction (HMI) plays a crucial role in bridging humans with machines and popularizing the internet of things. − Typically, tactile sensing is a key step in converting tactile actions into electrical signals for machines. , Various traditional sensors were studied for smart sensing, such as capacitive, , resistive, − and optical sensors, , which endure the problem of supplying external energy. Notably, the triboelectric sensor (TES) based on the coupling of triboelectric and electrostatic effects is designed to detect movement under a low-pressure range in the self-powered mode. − Due to the merits of unique self-powering, small size, high sensitivity, fast response, and low detection limits, the TES not only is conducive to solving the problem of replacing the power supply but also shows crucial potential in portable sensing for establishing HMI systems. − …”

Section: Introductionmentioning

confidence: 99%

Performance-Enhanced Flexible Self-Powered Tactile Sensor Arrays Based on Lotus Root-Derived Porous Carbon for Real-Time Human–Machine Interaction of the Robotic Snake

Tu,

Fang,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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Flexible tactile sensors play an important role in the development of wearable electronics and human−machine interaction (HMI) systems. However, poor sensing abilities, an indispensable external energy supply, and limited material selection have significantly constrained their advancement. Herein, a self-powered flexible triboelectric sensor (TES) is proposed by integrating lotus-root-derived porous carbon (PC) into polydimethylsiloxane (PDMS). Owing to the superior charge capturing capability of PC, the PDMS/PC (PPC)-based TES exhibits an open-circuit voltage (V oc ) of 22.8 V when it is periodically patted by skin at the pressure of 2 N and the frequency of 1 Hz, which is 5 times higher than that of a pristine PDMS-based TES. Furthermore, the as-prepared self-powered TES exhibits a high sensitivity of 3.24 V kPa −1 below 15 kPa for detecting human motion signals, such as finger clicks, joint bends, etc. Last but not the least, after the assembly of a PPC-based TES array and construction of an HMI system, the robotic snake can be controlled remotely by recognizing finger touching signals. This work shows broad potential applications for the self-powered TES in the fields of intelligent robotics, flexible electronics, disaster relief, and intelligence spying.

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“…Distributed mechanical energy has been effectively harnessed by triboelectric nanogenerators (TENGs) based on the triboelectric effect and electrostatic induction. 1–6 Owing to their low cost, material diversity, low-frequency applicability and light weight, 7 TENGs are increasingly playing a significant role in various fields, covering micro/nano power sources, 8,9 self-powered sensing, 10,11 blue energy, 12,13 and high-voltage power sources. 14,15 However, the low energy density of TENGs, compared with commercial batteries, severely limits their practical usefulness in energy powering applications.…”

Section: Introductionmentioning

confidence: 99%

Triboelectric nanogenerators exhibiting ultrahigh charge density and energy density

Liu,

Zhao,

Gao

et al. 2024

Energy Environ. Sci.

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Recent Advances in Triboelectric Nanogenerators for Marine Exploitation

Cited by 42 publications

References 254 publications

Ultrasound-driven triboelectric and piezoelectric nanogenerators in biomedical application

Ultrasound-driven triboelectric and piezoelectric nanogenerators in biomedical application

Performance-Enhanced Flexible Self-Powered Tactile Sensor Arrays Based on Lotus Root-Derived Porous Carbon for Real-Time Human–Machine Interaction of the Robotic Snake

Triboelectric nanogenerators exhibiting ultrahigh charge density and energy density

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