Core–Sheath Fiber-Based Triboelectric Nanogenerators for Energy Harvesting and Self-Powered Straight-Arm Sit-Up Sensing

Yu, Bin; Jing, Long; Huang, Tao; Xiang, Zhen; Liu, Mengjiao; Zhang, X. N.; Jiang-hua, Zhu; Yu, Hao

doi:10.1021/acsomega.3c04090

Cited by 5 publications

(1 citation statement)

References 42 publications

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“…Researchers are exploring new sustainable and environmentally friendly materials, green manufacturing methods, end-of-the-life processes, and standardized sustainability assessment methods, such as life cycle analysis, recyclability, and biodegradability [23,161,162]. Second, numerous positive contributions of smart textiles to sustainability are highlighted in the following areas [163]: environmental monitoring (temperature and humidity sensors, gas sensors) [164][165][166]; fresh water purification and harvesting (filtering, mist collection, collection by coalescence or mechanical squeezing) [167][168][169]; personal protection (warming, cooling, electromagnetic protection, EMI shielding, protection against UV radiation, toxic substances and microorganisms) [35,37,138,[170][171][172][173]; power supply on the body with energy harvesting and storage (triboelectric nanogenerators [174][175][176][177][178][179][180], including thermoelectric generators [134,181,182], photovoltaic textiles [183][184][185], bio-physicochemical energy harvesting [186], textiles with perovskite solar cells and other perovskite materials [187,188], dry batteries and flexible electrodes [189][190][191][192], and wearable all-in-one power sources that integrate energy harvesting and storage capability into one textile…”

Section: An Overview Of New Trends-the Latest Concepts and Propulsive...mentioning

confidence: 99%

Smart Textiles: A Review and Bibliometric Mapping

Sajovic,

Kert,

Boh Podgornik

2023

Preprint

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According to ISO/TR 23383, smart textiles reversibly interact with their environment and respond or adapt to changes in the environment. The present review and bibliometric analysis was performed on 5,810 documents (1989–2022) from the Scopus database, using VOSviewer and Bibliometrix/Biblioshiny for science mapping. The results show that the field of smart textiles is highly interdisciplinary and dynamic, with an average growth rate of 22% and exponential growth in the last 10 years. Beeby, S.P., and Torah, R.N. have published the highest number of papers, while Wang, Z.L. has the highest number of citations. The leading journals are Sensors, ACS Applied Materials and Interfaces, and Textile Research Journal, while Advanced Materials has the highest number of citations. China is the country with the most publications and the most extensive cooperative relationships with other countries. Research on smart textiles is largely concerned with new materials and technologies, particularly in relation to electronic textiles. Recent research focuses on energy generation (triboelectric nanogenerators, thermoelectrics, Joule heating), conductive materials (MXenes, liquid metal, silver nanoparticles), sensors (strain sensors, self-powered sensors, gait analysis), specialty products (artificial muscles, soft robotics, EMI shielding), and advanced properties of smart textiles (self-powered, self-cleaning, washable, sustainable smart textiles).

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Section: An Overview Of New Trends-the Latest Concepts and Propulsive...mentioning

confidence: 99%

Smart Textiles: A Review and Bibliometric Mapping

Sajovic,

Kert,

Boh Podgornik

2023

Preprint

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Advances in Wearable Multifunctional Devices Based on Human‐Body Energy Harvesting

Chu,

Xue,

Luo

et al. 2024

Adv Materials Technologies

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Wearable electronics with multi‐functionalities are widely utilized in various domains, including everyday living, healthcare, military training, and sports. Advances in flexible electronic technology, new materials, artificial intelligence technology, and sensor technology have accelerated the rapid development of smart wearable devices toward multifunctional and highly integrated trends. The energy supply technology based on the human‐body energy harvesting method endows wearable, multifunctional electronic devices with sustainable, renewable, and self‐powered characteristics, which proposes a solution strategy for the function expansion and energy supply of wearable devices. Herein, this paper discusses recent research on various methods of harvesting human body energy and wearing parts respectively, focusing on the new materials, structures, and processes involved in the representative studies, as well as the impact on energy harvesting and output, and functional applications. Furthermore, the challenges and obstacles faced in the creation of wearable multifunctional devices based on human self‐sufficiency and propose solution strategies to propel them in order to advance the creation of the next wave of intelligent wearable technology are also discussed.

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Ultra-stretchable and high performance fibrous TENG with helically structured dual-channel Liquid Metal electrode

Xing,

Zhang,

et al. 2024

Chemical Engineering Journal

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Core–Sheath Fiber-Based Triboelectric Nanogenerators for Energy Harvesting and Self-Powered Straight-Arm Sit-Up Sensing

Cited by 5 publications

References 42 publications

Smart Textiles: A Review and Bibliometric Mapping

Smart Textiles: A Review and Bibliometric Mapping

Advances in Wearable Multifunctional Devices Based on Human‐Body Energy Harvesting

Ultra-stretchable and high performance fibrous TENG with helically structured dual-channel Liquid Metal electrode

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