Advances in magnetic-assisted triboelectric nanogenerators: structures, materials and self-sensing systems

Abstract Triboelectric nanogenerators (TENG), renowned for their remarkable capability to harness weak mechanical energy from the environment, have gained considerable attention owing to their cost-effectiveness, high output, and adaptability. This review provides a unique perspective by conducting...

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Published inInternational Journal of Extreme Manufacturing Vol. 6; no. 5; pp. 52007 - 52033
Main Authors Wu, Pengfan, Zhao, Chenxi, Cui, Endian, Xu, Shiwei, Liu, Tao, Wang, Fayang, Lee, Chengkuo, Mu, Xiaojing
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.10.2024
Subjects
controlled material preparation
Cost effectiveness
Ferrofluids
magnetic assistance
Man-machine interfaces
Nanocomposites
Nanogenerators
self-powered system
Suction
triboelectric nanogenerator
tuning structure
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Abstract Abstract Triboelectric nanogenerators (TENG), renowned for their remarkable capability to harness weak mechanical energy from the environment, have gained considerable attention owing to their cost-effectiveness, high output, and adaptability. This review provides a unique perspective by conducting a comprehensive and in-depth analysis of magnetically assisted TENGs that encompass structures, materials, and self-powered sensing systems. We systematically summarize the diverse functions of the magnetic assistance for TENGs, including system stiffness, components of the hybrid electromagnetic-triboelectric generator, transmission, and interaction forces. In the material domain, we review the incorporation of magnetic nano-composites materials, along with ferrofluid-based TENG and microstructure verification, which have also been summarized based on existing research. Furthermore, we delve into the research progress on physical quantity sensing and human-machine interface in magnetic-assisted TENGs. Our analysis highlights that magnetic assistance extends beyond the repulsive and suction forces under a magnetic field, thereby playing multifaceted roles in improving the output performance and environmental adaptability of the TENGs. Finally, we present the prevailing challenges and offer insights into the future trajectory of the magnetic-assisted TENGs development. Highlights Magnetic assistant is introduced as a means to improve the dynamic response range of the triboelectric nanogenerator and orderly control performance of the tribo-materials. The most significant function of magnetic assistance lies in the environmental adaptability and potential applications of triboelectric nanogenerators. The latest progresses in the materials, structures, and self-sensing systems of magnetic-assisted triboelectric nanogenerators are systemically reviewed. The advantages, challenges, and future outlook of magnetically assisted triboelectric nanogenerator technology are discussed.
AbstractList Triboelectric nanogenerators (TENG), renowned for their remarkable capability to harness weak mechanical energy from the environment, have gained considerable attention owing to their cost-effectiveness, high output, and adaptability. This review provides a unique perspective by conducting a comprehensive and in-depth analysis of magnetically assisted TENGs that encompass structures, materials, and self-powered sensing systems. We systematically summarize the diverse functions of the magnetic assistance for TENGs, including system stiffness, components of the hybrid electromagnetic-triboelectric generator, transmission, and interaction forces. In the material domain, we review the incorporation of magnetic nano-composites materials, along with ferrofluid-based TENG and microstructure verification, which have also been summarized based on existing research. Furthermore, we delve into the research progress on physical quantity sensing and human-machine interface in magnetic-assisted TENGs. Our analysis highlights that magnetic assistance extends beyond the repulsive and suction forces under a magnetic field, thereby playing multifaceted roles in improving the output performance and environmental adaptability of the TENGs. Finally, we present the prevailing challenges and offer insights into the future trajectory of the magnetic-assisted TENGs development.
Abstract Triboelectric nanogenerators (TENG), renowned for their remarkable capability to harness weak mechanical energy from the environment, have gained considerable attention owing to their cost-effectiveness, high output, and adaptability. This review provides a unique perspective by conducting a comprehensive and in-depth analysis of magnetically assisted TENGs that encompass structures, materials, and self-powered sensing systems. We systematically summarize the diverse functions of the magnetic assistance for TENGs, including system stiffness, components of the hybrid electromagnetic-triboelectric generator, transmission, and interaction forces. In the material domain, we review the incorporation of magnetic nano-composites materials, along with ferrofluid-based TENG and microstructure verification, which have also been summarized based on existing research. Furthermore, we delve into the research progress on physical quantity sensing and human-machine interface in magnetic-assisted TENGs. Our analysis highlights that magnetic assistance extends beyond the repulsive and suction forces under a magnetic field, thereby playing multifaceted roles in improving the output performance and environmental adaptability of the TENGs. Finally, we present the prevailing challenges and offer insights into the future trajectory of the magnetic-assisted TENGs development. Highlights Magnetic assistant is introduced as a means to improve the dynamic response range of the triboelectric nanogenerator and orderly control performance of the tribo-materials. The most significant function of magnetic assistance lies in the environmental adaptability and potential applications of triboelectric nanogenerators. The latest progresses in the materials, structures, and self-sensing systems of magnetic-assisted triboelectric nanogenerators are systemically reviewed. The advantages, challenges, and future outlook of magnetically assisted triboelectric nanogenerator technology are discussed.
Author Cui, Endian
Xu, Shiwei
Wang, Fayang
Mu, Xiaojing
Zhao, Chenxi
Liu, Tao
Lee, Chengkuo
Wu, Pengfan
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Snippet Abstract Triboelectric nanogenerators (TENG), renowned for their remarkable capability to harness weak mechanical energy from the environment, have gained...
Triboelectric nanogenerators (TENG), renowned for their remarkable capability to harness weak mechanical energy from the environment, have gained considerable...
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SourceType Open Website
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StartPage 52007
SubjectTerms controlled material preparation
Cost effectiveness
Ferrofluids
magnetic assistance
Man-machine interfaces
Nanocomposites
Nanogenerators
self-powered system
Suction
triboelectric nanogenerator
tuning structure
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Title Advances in magnetic-assisted triboelectric nanogenerators: structures, materials and self-sensing systems
URI https://iopscience.iop.org/article/10.1088/2631-7990/ad5bc6
https://www.proquest.com/docview/3076284817/abstract/
https://doaj.org/article/52af4741ee5546f3b5cff6ae924d59b8
Volume 6
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