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Start Over Descriptor "Triboelectric nanogenerator" Topic energy harvesting
911 results on '"Triboelectric nanogenerator"'

17. Anisotropic conductive eutectogels for strain sensing and triboelectric nanogeneration in extreme environments.

Author

Guo, Bingyan, He, Shaoshuai, Li, Linfa, Chen, Shuang, Guo, Zhicheng, Yao, Mengmeng, Xiao, Yutong, Liu, Min, Liang, Lei, Qiu, Yuwei, Zhang, Hong, Yao, Fanglian, and Li, Junjie

Subjects
*STRAIN sensors, *ELECTRONIC equipment, *ENERGY harvesting, *ELECTRIC conductivity, *ELASTIC modulus
Abstract

[Display omitted] Conductive hydrogels have attracted widespread attention for their promising application prospects in portable and flexible electronic devices. However, hydrogels commonly suffer from problems such as solvent volatilization and freezing at low temperatures. Inspired by tissues such as human muscles, tendons, and ligaments, this study proposes a facile method to produce anisotropic conductive strong and tough eutectogels through directional freezing integrated with solvent substitution (DFSS) strategy. Eutectogels with anisotropic characteristics exhibit a highly anisotropic structure, conferring distinctive anisotropic mechanical properties and electrical conductivity. The prepared anisotropic PVA-M-DES eutectogels exhibit excellent mechanical properties (high strength of 6.31 MPa, high toughness of 20.75 MJ m−3, elastic modulus of 2.36 MPa, and fracture strain of 596%), high conductivity (0.17 S m−1), excellent anti-freezing and anti-drying properties. Environment-tolerant anisotropic PVA-M-DES eutectogels can be assembled into strain sensor and triboelectric nanogenerator to achieve real-time monitoring of various human motions and have potential applications in wearable electronics, personal healthcare, energy harvesting, and human–machine interfaces. [ABSTRACT FROM AUTHOR]

Published
2025
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18. Advances in TENGs for Marine Energy Harvesting and In Situ Electrochemistry.

Author

Zhang, Chuguo, Hao, Yijun, Lu, Xiangqian, Su, Wei, Zhang, Hongke, Wang, Zhong Lin, and Li, Xiuhan

Subjects
*ENERGY harvesting, *CARBON offsetting, *STRUCTURAL design, *SUSTAINABLE development, *ENERGY research
Abstract

Highlights: The basic information of triboelectric nanogenerator (TENG), the power conversion process, and key points of the marine energy harvesting TENGs was introduced in detail. An in-depth introduction and analysis of relevant research with the marine energy harvesting were conducted through gradient classification. This review not only provided a deeper summary of the latest research progress, discoveries, and challenges, but also made a rational outlook on solutions to related issues and future development directions. The large-scale use of ample marine energy will be one of the most important ways for human to achieve sustainable development through carbon neutral development plans. As a burgeoning technological method for electromechanical conversion, triboelectric nanogenerator (TENG) has significant advantages in marine energy for its low weight, cost-effectiveness, and high efficiency in low-frequency range. It can realize the efficient and economical harvesting of low-frequency blue energy by constructing the floating marine energy harvesting TENG. This paper firstly introduces the power transfer process and structural composition of TENG for marine energy harvesting in detail. In addition, the latest research works of TENG on marine energy harvesting in basic research and structural design are systematically reviewed by category. Finally, the advanced research progress in the power take-off types and engineering study of TENG with the marine energy are comprehensively generalized. Importantly, the challenges and problems faced by TENG in marine energy and in situ electrochemical application are summarized and the corresponding prospects and suggestions are proposed for the subsequent development direction and prospects to look forward to promoting the commercialization process of this field. [ABSTRACT FROM AUTHOR]

Published
2025
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19. Hybridized triboelectric nanogenerators for simultaneously scavenging droplet and wind energies.

Author

Hu, Chaosheng, Bao, Chengmin, Liu, Yang, Yan, Yingzhan, Bai, Yanan, and Xu, Qian

Subjects
*NANOGENERATORS, *ENERGY harvesting, *WIND power, *INTERNET of things, *MANUFACTURING processes
Abstract

Triboelectric nanogenerators (TENGs) have attracted great attention due to the simple manufacturing process, low cost, and diverse forms of energy harvesting. However, the energy collected by individual TENG is relatively limited, making it necessary to develop new method to enhance the energy harvesting capability of TENG. Here, we design a hybridized TENG that integrates a droplet-driven TENG and a wind-driven TENG, which exhibits excellent electrical performance. Under the simulated environment of medium rain with medium breeze, the hybridized TENG generates an output voltage of 95.10 V, a maximum average power of 18.15 μW, an energy of 181.54 μJ in 10 s, and charges a 1 μF capacitor to 43.29 V in 120 s. This work enables the harvesting of dispersed wind and droplet energy from the environment, providing new ideas and possibilities for online monitoring in remote areas and the construction of Internet of Things systems. [ABSTRACT FROM AUTHOR]

Published
2025
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20. Modulating Contact Electrification With Metal‐Organic Frameworks in Flexible Triboelectric Nanogenerators for Kinetic Energy Harvesting and Self‐Powered Humidity Sensing Applications.

Author

Kallupadi, Vaishna Priya, Varghese, Harris, Hareesh, Unnikrishnan Nair Saraswathy, and Chandran, Achu

Subjects
*NANOGENERATORS, *ENERGY harvesting, *MECHANICAL energy, *KINETIC energy, *CHARGE exchange, *POLYACRYLONITRILES
Abstract

Herein, we present a novel method for fabricating a triboelectric nanogenerator using Polyacrylonitrile (PAN) on both sides as triboelectric pairs, incorporating metal‐organic frameworks (MOFs) such as ZIF‐8, ZIF‐67, MIL‐100, and HKUST‐1 during the electrospinning process. The triboelectric properties of the MOF‐incorporated fibers are thus tailored and positioned within the triboelectric series for the first time. The resulting triboelectric polarity of the composite fiber is linked to the optical bandgap energy of the PAN and the MOF/PAN composite, facilitating electron transfer between materials of different work functions and leading to enhanced output in the developed triboelectric devices. Fascinatingly, the appropriate choice of MOF filler also displayed the potential for reversing the triboelectric polarity of PAN nanofiber. Consequently, incorporating ZIF‐8 and MIL‐100 into PAN nanofibers led notably to contrasting trends in triboelectric polarity, with the pair generating an open‐circuit output voltage of 100 V, short‐circuit current of 1.35 μA, and a power density of 18.4 mW/m2 respectively. The fabricated device demonstrated effectiveness for mechanical energy harvesting applications and also as a self‐powered humidity sensor, displaying rapid response to changes in ambient humidity levels with a maximum sensitivity of 2.14 V/%RH, for relative humidity range between 50 and 90% during the humidifying cycle. [ABSTRACT FROM AUTHOR]

Published
2025
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21. Recent Progress in Self-Healing Triboelectric Nanogenerators for Artificial Skins.

Author

Li, Guoliang, Li, Zongxia, Hu, Haojie, Chen, Baojin, Wang, Yuan, Mao, Yanchao, Li, Haidong, and Zhang, Baosen

Subjects
NANOGENERATORS, ARTIFICIAL skin, ENERGY harvesting, SYSTEM integration, WEARABLE technology, SELF-healing materials
Abstract

Self-healing triboelectric nanogenerators (TENGs), which incorporate self-healing materials capable of recovering their structural and functional properties after damage, are transforming the field of artificial skin by effectively addressing challenges associated with mechanical damage and functional degradation. This review explores the latest advancements in self-healing TENGs, emphasizing material innovations, structural designs, and practical applications. Key materials include dynamic covalent polymers, supramolecular elastomers, and ion-conductive hydrogels, which provide rapid damage recovery, superior mechanical strength, and stable electrical performance. Innovative structural configurations, such as layered and encapsulated designs, optimize triboelectric efficiency and enhance environmental adaptability. Applications span healthcare, human–machine interfaces, and wearable electronics, demonstrating the immense potential for tactile sensing and energy harvesting. Despite significant progress, challenges remain in scalability, long-term durability, and multifunctional integration. Future research should focus on advanced material development, scalable fabrication, and intelligent system integration to unlock the full potential of self-healing TENGs. This review provides a comprehensive overview of current achievements and future directions, underscoring the pivotal role of self-healing TENGs in artificial skin technology. [ABSTRACT FROM AUTHOR]

Published
2025
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22. MnO2 Nanowires with Sub‐10 nm Thick Conjugated Microporous Polymers as Synergistic Triboelectric Materials.

Author

Jung, Hanbyeol, Lee, Dong‐Min, Park, Jina, Kim, Taeho, Kim, Sang‐Woo, and Son, Seung Uk

Subjects
*ENERGY harvesting, *POWER resources, *NANOGENERATORS, *CONJUGATED polymers, *ELECTRONIC equipment, *NANOWIRES
Abstract

MnO2 nanowires coated with conjugated microporous polymers (CMP) are applied as triboelectric energy harvesting materials. The tribopositive performance of the CMP shells is enhanced with the assistance of MnO2 nanowires (MnO2 NW), likely due to cationic charge transfer from the tribopositive CMP layers to the surface Mn2+ and Mn3+ species of MnO2 NW. This is supported by model studies. The MnO2@CMP‐2 with sub‐10 nm thick CMP layers shows promising triboelectric output voltages up to 576 V and a maximum power density of 1.31 mW cm−2. Spring‐assisted triboelectric nanogenerators fabricated with MnO2@CMP‐2/PVP‐3 films are used as power supplies to operate electronic devices. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Enhance Charge Transfer and Reduce Internal Resistance for Triboelectric Nanogenerator via Switching Charge Shuttling.

Author

Guo, Xin, Wang, Yuqi, Feng, Yuming, Yu, Yang, Wang, Jianlong, He, Siyang, Zhu, Jinzhi, Li, Hengyu, Cheng, Tinghai, Wang, Zhong Lin, and Cheng, Xiaojun

Subjects
*NANOGENERATORS, *MARINE pollution, *WAVE energy, *ENERGY storage, *CAPACITORS, *ENERGY harvesting
Abstract

Traditional triboelectric nanogenerators (TENGs) face significant challenges related to low charge density and high internal impedance. Many methods have been proposed to enhance the surface charge density of TENGs, yet they do not simultaneously achieve low internal resistance. Here, a switch‐shuttling triboelectric nanogenerator (SS‐TENG) is proposed. By periodically interrupting the circuit during the intrinsic capacitance variation of the TENG during the charge shuttle process, the SS‐TENG alters the potential difference while maintaining a constant charge in the capacitor, thereby enhancing energy storage and improving overall output performance. The rapid activation of the switch significantly reduces internal resistance. Compared to traditional charge shuttle TENGs, the charge transfer amount increases by 1.9 times, while the short‐circuit current rises by 9.6 times, with internal resistance reduced by a factor of 20. Furthermore, a prototype of the novel cylindrical‐hexagram bluff body (CHB) vortex‐induced vibration energy harvester based on the SS‐TENG is designed and tested, demonstrating its ability to reliably harvest energy from underwater tidal flows and surface wave energy. Additionally, a self‐powered marine pollution detection strategy has been developed using the SS‐TENG. This work provides valuable insights for enhancing the performance of TENGs and actively promotes their commercialization. [ABSTRACT FROM AUTHOR]

Published
2024
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24. The Distance‐Dependent Electric Field Theory for Sliding Mode Triboelectric Nanogenerators.

Author

Bulathsinghala, Rameesh L., Deane, Jonathan H.B., and Dharmasena, R.D. Ishara G.

Subjects
*NANOGENERATORS, *ENERGY harvesting, *ELECTRIC impedance, *POTENTIAL energy, *ELECTRIC fields
Abstract

Triboelectric nanogenerators (TENGs) have demonstrated outstanding potential as energy harvesters and sensors for future wearable electronics. However, TENGs still require major improvements in their theory and optimization, especially for the sliding‐mode designs. Addressing this gap, a novel theoretical model based on the distance‐dependent electric field (DDEF) theory for sliding mode TENGs is presented here. The model is used to simulate the electrical outputs and impedance behaviour of a sliding mode TENG, and the results are verified experimentally. The outcomes indicate that compared to existing theoretical models, this new model provides higher accuracy in representing experimental TENG. Next, all the primary parameters (material, structural and motion parameters) which affect the sliding mode TENG are analyzed, uncovering new optimization strategies and more comprehensive parametric analysis compared to previous models. More importantly, the theoretical approach is equally applicable to sliding mode TENG as well as contact‐separation mode TENG. This eliminates the need for bespoke capacitor models for each TENG type, leading to a universal theoretical platform for TENGs. The new model facilitates cross‐comparison between different TENG working modes, uncovering a range of previously unreported output trends. Hence, this work significantly expands the understanding of TENGs, paving way to more efficient future device designs. [ABSTRACT FROM AUTHOR]

Published
2024
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25. A Triboelectric Nanogenerator Utilizing a Crank-Rocker Mechanism Combined with a Spring Cantilever Structure for Efficient Energy Harvesting and Self-Powered Sensing Applications.

Author

Wang, Xinhua, Xu, Xiangjie, Sun, Tao, and Yin, Gefan

Subjects
ENERGY harvesting, NANOGENERATORS, INDUSTRIAL robots, FREQUENCIES of oscillating systems, INDUSTRIAL capacity
Abstract

With the advancement of industrial automation, vibrational energy generated by machinery during operation is often underutilized. Developing efficient devices for vibration energy harvesting is thus essential. Triboelectric nanogenerators (TENGs) based on spring and cantilever beam structures show considerable potential for industrial vibration energy harvesting; however, traditional designs often fail to fully harness vibrational energy due to their structural limitations. This study proposes a triboelectric nanogenerator (TENG) based on a crank-rocker mechanism and a spring cantilever structure (CR-SC TENG), which combines a crank-rocker mechanism with a spring cantilever structure, designed for both energy harvesting and self-powered sensing. The CR-SC TENG incorporates a spring cantilever beam, a crank-rocker mechanism, and lever amplification principles, enabling it to respond sensitively to low-frequency, small-amplitude vibrations. Utilizing the crank-rocker and lever effects, this device significantly amplifies micro-amplitudes, enhancing energy capture efficiency and making it well suited for low-amplitude, complex industrial environments. Experimental results demonstrate that this design effectively amplifies micro-vibrations and markedly improves energy conversion efficiency within a frequency range of 1–35 Hz and an amplitude range of 1–3 mm. As a sensor, the CR-SC TENG's dual-generation units produce output signals that precisely reflect vibration frequencies, making it suitable for the intelligent monitoring of industrial equipment. When placed on an air compressor operating at 25 Hz, the first-generation unit achieved an output voltage of 150 V and a current of 8 μA, while the second-generation unit produced an output voltage of 60 V and a current of 5 μA. These findings suggest that the CR-SC TENG, leveraging spring cantilever beams, crank-rocker mechanisms, and lever amplification, has significant potential for micro-amplitude energy harvesting and could play a key role in smart manufacturing, intelligent factories, and the Internet of Things. [ABSTRACT FROM AUTHOR]

Published
2024
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26. An Extreme Environment Capable Self‐Healing Single Active Layered Triboelectric Sensors as Fully Recyclable and Transparent Human‐Machine Interfaces.

Author

Liu, Mengmeng, Li, Pengju, Tan, Yu Jun, Yang, Zijie, See, Hian Hian, Yang, Weidong, Liang, Fang‐Cheng, Cheng, Xu, and Tee, Benjamin C. K.

Subjects
*CONVOLUTIONAL neural networks, *OBJECT recognition (Computer vision), *EXTREME environments, *ENERGY harvesting, *DIELECTRIC materials
Abstract

Current approaches to triboelectric devices require multiple layers. Here, a transparent ultra‐stretchable single active layered ionic‐based nanogenerator is shown that can self‐heal in both dry and wet environments. Despite being conductive, surprisingly the ionogel exhibits triboelectric properties and generates output voltages ranging from 1.7 to 70 V. By tuning the ionic liquid concentration, unique triboelectric devices with position‐detection and energy harvesting ability are developed. This design enables visualization of the mechanical force distribution through the mechano‐electric‐optical conversion process, which is achieved by changing it from an insulating dielectric material to a tribo‐negative ionic conducting material. The triboelectric device maintains its stability and self‐healing ability at extreme environments (−20 to 380 °C, pH 1.3 to 13), and the device can be fully closed‐loop recycled for reuse. Various human‐machine interface applications such as untethered self‐powered light‐emitting jellyfish‐like devices are demonstrated, a mechano‐thermal sensor array, and tactile recognition of object shapes with over 91% accuracy using convolution neural networks (CNN). [ABSTRACT FROM AUTHOR]

Published
2024
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27. Wearable Multifunctional Bilayer Nanofiber Films for Human Motion Energy Harvesting and Photothermal Therapy.

Author

Shen, Shaowei, Wu, Haoyi, Xu, Zihan, Cao, Ruirui, Liu, Ying, Zhao, Yangjiu, Li, Xin, Yu, Haoran, Chen, Chong, Wang, Xinya, and Pan, Caofeng

Subjects
*NANOGENERATORS, *ENERGY harvesting, *PHOTOTHERMAL conversion, *MECHANICAL energy, *ENERGY conversion, *PHOTOTHERMAL effect
Abstract

In light of the escalating requisites for portability, functionality, comfort, and health in electronic apparatus, the imperative advancement of sophisticated multifunctional textile‐based triboelectric nanogenerators (textile‐TENGs) is underscored. This research delineates the fabrication of an innovative multifunctional textile‐TENG, comprising a photosensitive stratum aimed at thermal regulation and photothermal therapy, alongside a tribo‐negative nanofiber film adorning its verso. Exhibiting superlative electrical prowess, the textile‐TENG generates remarkably elevated outputs over a wide temperature range, thereby facilitating the efficacious conversion of kinetic energy derived from human motion into electrical energy. Concurrently, the device manifests an exceptional photothermal conversion efficiency, achieving instantly modifiable saturation temperatures (41.52–60.97 °C) under diverse solar exposures, rendering it eminently suitable for a broad spectrum of applications in thermal therapy and regulation domains. Significantly, within cold environments, the textile‐TENG demonstrates a capability to augment temperature by approximately 7.4 °C, markedly surpassing conventional cotton textiles in performance. In summation, the textile‐TENG is characterized by its unparalleled electromechanical attributes and photothermal conversion efficacies, concurrently facilitating thermal regulation, therapy, and electricity generation. This investigation not only furnishes a referential methodology for the development of advanced multifunctional textile devices but also substantially expands the conceivable application ambit of textile‐based technologies. [ABSTRACT FROM AUTHOR]

Published
2024
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28. Effect of Fluorine and Copper Ions on Liquid‐Solid Triboelectric Nanogenerator.

Author

Salman, Mohamed, Sorokin, Vladislav, Li, Zifan, Zhu, Yuting, Gan, Wee Chen, and Aw, Kean

Subjects
*COPPER ions, *DEIONIZATION of water, *ENERGY harvesting, *COPPER sulfate, *CATIONS, *TRIBOELECTRICITY
Abstract

Liquid‐solid triboelectric nanogenerator (LS‐TENG) harvests energy efficiently while eliminating wear issues associated with solid‐solid TENG. However, the effect of ions or charges in the liquid on output performance needs further examination. In this work, the impact of fluorine and copper ions introduced through deionized water with sodium fluoride (DI‐NaF) and deionized water with copper sulfate (DI‐CuSO4) solution on the output voltage, charge and current of a tubular LS‐TENG with polytetrafluoroethylene (PTFE) and Nylon as solid materials is examined. The results indicate that fluorine and copper ions have opposite effects on PTFE and Nylon LS‐TENG's output. The fluorine (F−) ions enhance the triboelectric effect and charge transfer in Nylon LS‐TENG, increasing output, while they hinder the charge transfer process in PTFE LS‐TENG, consequently decreasing its output. Conversely, the copper (Cu2+) ions have a positive effect on the output of PTFE LS‐TENG and a detrimental effect on Nylon LS‐TENG's output. Moreover, the results indicate that LS TENG's output performance depends on the charges of solid and liquid triboelectric materials. Thus, this study provides insights into material‐ion interaction in LS‐TENG and underscores the importance of triboelectric material selection for optimizing output performance. [ABSTRACT FROM AUTHOR]

Published
2024
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29. Enhanced Machine Condition Monitoring Based on Triboelectric Nanogenerator (TENG): A Review of Recent Advancements.

Author

Mehamud, Idiris, Björling, Marcus, Marklund, Pär, An, Rong, and Shi, Yijun

Subjects
NANOGENERATORS, ENERGY harvesting, TECHNOLOGICAL innovations, MACHINE performance, DATA transmission systems
Abstract

Intelligent machine condition monitoring is desirable to enable Industry 4.0 and 5.0 to create sustainable products and services via the integration of automation, data exchange, and human–machine interface. In the past decades, huge progress has been achieved in establishing sustainable machine condition monitoring systems via various sensing technologies. Yet, the dependence on external power sources or batteries for sensing and data communication remains a challenge. In addition, energy harvesting and sensing are dynamically growing research fields introducing various working mechanisms and designs for improved performance, flexibility, and integrability. Recently, triboelectric nanogenerators (TENG) have been applied as a new technology for energy harvesting and sensing to monitor machine performance. This manuscript presents the potential application of TENG for self‐powered sensors and energy harvesting technology for machine condition monitoring, where the developmental aspects of TENG‐based devices including the robustness of design and device integration to machine elements are reviewed. For better comparison, the performance of various reported devices is summarized. Simultaneously, the advanced results achieved in employing TENGs for various condition analysis techniques and self‐powered wireless communication for machine condition monitoring are discussed. Finally, the challenges, and key strategies for utilizing TENGs for machine condition monitoring in the future, are presented. [ABSTRACT FROM AUTHOR]

Published
2024
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30. Current Trends on Advancement in Smart Textile Device Engineering.

Author

Behera, Swayam Aryam, Panda, Swati, Hajra, Sugato, Kaja, Kushal Ruthvik, Pandey, Adarsh Kumar, Barranco, Angel, Jeong, Soon Moon, Vivekananthan, Venkateswaran, Kim, Hoe Joon, and Achary, P. Ganga Raju

Subjects
ELECTROTEXTILES, DATA privacy, MELT spinning, SMART devices, ENERGY harvesting
Abstract

Smart textiles represent a revolutionary approach to wearable technology with applications ranging from healthcare to energy harvesting. This review paper explores the importance of textile technologies and highlights their potential to revolutionize consumer electronics. Conventional technologies are sometimes heavy, and lack comfort and flexibility, but smart textiles seamlessly integrate into everyday clothing, improving wearability and user experience. The article emphasizes the need for sustainable sourcing and environmentally friendly production methods, as well as responsible manufacturing and disposal practices. Manufacturing techniques such as wet spinning, melt spinning, electrostatic spinning, weaving, knitting, and printing are detailed and shed light on their role in incorporating electronics into textiles. Several applications of textile‐based devices are being explored, including biochemical sensing, temperature monitoring, energy harvesting, energy storage, and smart displays. Each application demonstrates the versatility and potential of smart textiles in different areas. Despite optimistic progress, challenges remain, from improving energy efficiency to protecting user privacy and data security. The review analyzes these problems and suggests future improvements, including interdisciplinary collaboration to find new solutions. Finally, an overview of the current state of smart textiles provides the future of this technology. It serves as an in‐depth reference for academics and readers interested in understanding recent advances and discoveries in textile technologies, highlighting the importance of this rapidly growing industry. [ABSTRACT FROM AUTHOR]

Published
2024
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31. Mode-Adaptive Surface Pattern Design for Enhanced Triboelectric Nanogenerator Performance.

Author

Kisomi, Masoumeh Karimi, Roomi, Muhammad Sohaib, and Mahmud, M. A. Parvez

Subjects
OPEN-circuit voltage, ENERGY harvesting, NANOGENERATORS, MECHANICAL energy, ELECTRICAL energy, ELECTROSTATIC induction, TRIBOELECTRICITY
Abstract

Triboelectric nanogenerators (TENGs) are a promising technique for harvesting environmental energy that is based on electrostatic induction and contact electrification. This is a method that uses every relative motion between two electrodes to convert mechanical energy into electrical energy. Several modes of TENGs are designed based on various relative motions between electrode pairs. As TENGs are a surface phenomenon, properties such as the structure of the electrodes are key parameters that affect their performance. In this paper, in order to identify the best pattern designed adapted to the TENG mode, the effect of surface structures in each mode is investigated numerically. To achieve the best performance of the micro-patterned electrode, a comparative study has been conducted on the four TENG modes under the same conditions. To reach this goal, micro-patterned shapes such as pyramid, spherical, and cube structures are designed, and the open circuit voltage is calculated and compared to a flat surface. The results show that surface modification has a significant role in TENG's performance. Based on this study, by using a cube-patterned electrode instead of a flat electrode, the output voltage increases from 233 V to 384 V in sliding mode. Also, by applying the spherical pattern, the output voltage is 1.7 times higher than a flat electrode in contact-separation mode. In the case of investigating TENG pattern structure, the results show that the electrical outputs of the patterned layer depend on the mode. The spherical pattern has a higher impact in contact-separation mode compared to the cube pattern. Meanwhile, in sliding mode, the cube pattern has a greater effect. This work provides a hint for designing an effective pattern on electrodes for a particular mode to enhance TENG performance. [ABSTRACT FROM AUTHOR]

Published
2024
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32. Diamond‐Structured Fabric‐Based Triboelectric Nanogenerators for Energy Harvesting and Healthcare Application.

Author

Ahmed, Taosif, Gao, Yuanyuan, So, Mei Yi, Tan, Di, Lu, Jian, Zhang, Junze, Wang, Qian, Liu, Xinlong, and Xu, Bingang

Subjects
*NANOGENERATORS, *ENERGY harvesting, *ELECTRIC power production, *PARKINSON'S disease, *WALKING speed
Abstract

Wearable technology is experiencing remarkable progress, prompting the need for sustainable power sources like triboelectric nanogenerators (TENGs). However, integrating TENGs into fabrics and insufficient power outputs that allows for comfortable wear without obstructing user's movements presents a significant challenge. In this study, a novel kind of diamond‐structured fabric‐based triboelectric nanogenerators (DSF‐TENGs) is introduced utilizing an easy, economical, and scalable weaving method without any chemical modification. Owing to its 3D diamond pattern, surface interactions are enhanced for greater charge generation together with strengthened mechanical engagement for more effective charge transfer. The DSF‐TENG, with its unique self‐resilient structure, achieves impressive electric performance, including output voltage of ≈763 V, short‐circuit current of ≈20.4 µA, and power density of 2862.78 mW m−2, which is multiple times higher than most existing fabric‐based TENGs. It also offers excellent air permeability of 560 mm s−1, consistent electricity generation and sensing even after ten washing cycles, and incredible durability, withstanding over 30 000 cycles. Furthermore, DSF‐TENG is included in an insole that is capable of sensing gait patterns, walking speed, and fall detections of patients with Parkinson's disease. The remarkable power generation capabilities of DSF‐TENG indicate a strong potential for future developments in wearable electronics and healthcare applications. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Triboelectric Series of Two‐dimensional Metal Carbide MXenes.

Author

Shi, Lin, Wang, Yizhou, Guo, Tianchao, Lei, Yongjiu, El‐Demellawi, Jehad K., Zhao, Zhiming, and Alshareef, Husam N.

Subjects
*NANOGENERATORS, *SURFACE potential, *ENERGY harvesting, *FLEXIBLE electronics, *WEARABLE technology
Abstract

The ever‐increasing prevalence of intelligent electronics underscores an escalating demand for sustainable power sources. Among the emerging energy harvesting technologies, triboelectric nanogenerators (TENGs) stand out as a promising solution for such pressing needs. To date, ongoing efforts have primarily focused on enhancing TENG output, particularly through the development of novel triboelectric materials. Among the potential candidates is the thriving class of two‐dimensional transition‐metal carbides, MXenes, which have predominantly been incorporated into triboelectric layers as nanofillers to enhance their triboelectric properties. Yet, the specific triboelectric characteristics of distinct MXenes remain marginally explored. Herein, the triboelectric properties of various metal carbide MXenes, i.e., V2CTx, Ti3C2Tx, and Nb2CTx, are investigated by assessing the performance of various MXene‐based TENGs combined with different polymers and analyzing their surface potential. According to the attained triboelectric polarities, a triboelectric series of the studied MXenes is determined, demonstrating their remarkable positive triboelectric properties. Further investigations preliminarily reveal the influence of the synthesis method, etchants, intercalating compounds, and postsynthesis procedures on the triboelectric properties of MXenes. Hence, beyond extending the conventional triboelectric series to different metal carbide MXenes, the findings present innovative perspectives on leveraging MXenes to develop high‐performance TENGs for flexible and wearable electronics. [ABSTRACT FROM AUTHOR]

Published
2024
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34. Novel Intercalation Approach in MXene Using Modified Silica Nanospheres to Enhance the Surface Charge Density for Superior Triboelectric Performance.

Author

Baig, Mirza Mahmood, Saqib, Qazi Muhammad, Noman, Muhammad, Sheeraz, Muhammad, Rasheed, Aamir, Yousuf, Muhammad, Lee, Eunho, Kim, Jungmin, Ko, Youngbin, Patil, Chandrashekhar S., Patil, Swapnil R., Ju, Hyuntae, Lee, Seung Goo, and Bae, Jinho

Subjects
*NANOGENERATORS, *ENERGY harvesting, *SURFACE charging, *STRUCTURAL stability, *PERMITTIVITY
Abstract

This paper proposes a novel intercalation approach to address the challenges of surface triboelectric charge dissipation and self‐restacking of MXene layers in triboelectric nanogenerators (TENGs). The proposed strategy significantly improves the performance of TENGs, as it prevents the loss of surface charges and enhances the structural stability of MXene. First, the modified silica nanospheres (MSNs) of specific dimensions are synthesized, followed by their intercalation between MXene layers. This not only resolves the restacking issue but also dramatically increases the interlayer distance and MXene's surface area. The MSNs, acting as effective charge storage sites, significantly enhance surface charge density, whereas their high dielectric permittivity generates a synergistic effect that modulates the dielectric constant via polarization. Ultimately, the proposed MSN‐intercalated MXene‐based TENG demonstrates outstanding output performance (output voltage of ≈461 V, output current of ≈19 µA, and maximum peak power density of ≈691.2 µW cm−2) at a 2 wt.% MSN‐intercalated MXene concentration. This study paves a new pathway for the structural design of tribonegative and charge storage layers in TENGs for energy harvesting. [ABSTRACT FROM AUTHOR]

Published
2024
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35. Triboelectric Nanogenerators Based on Transition Metal Carbo‐Chalcogenide (Nb2S2C and Ta2S2C) for Energy Harvesting and Self‐Powered Sensing.

Author

Xiao, Yana, Li, Zihua, Tan, Di, Carsten, Gachot, and Xu, Bingang

Subjects
*NANOGENERATORS, *ENERGY harvesting, *OPEN-circuit voltage, *ELECTRIC properties, *TRANSITION metals
Abstract

With burgeoning considerations over energy issues and carbon emissions, energy harvesting devices such as triboelectric nanogenerators (TENGs) are developed to provide renewable and sustainable power. Enhancing electric output and other properties of TENGs during operation is the focus of research. Herein, two species (Nb2S2C and Ta2S2C) of a new family of 2D materials, Transition Metal Carbo‐Chalcogenides (TMCCs), are first employed to develop TENGs with doping into Polydimethylsiloxane (PDMS). Compared with control samples, these two TMCC‐based TENGs exhibit higher electric properties owing to the enhanced permittivity of PDMS composite, and the best performance is achieved at a concentration of 3 wt. ‰ with open circuit voltage (Voc) of 112 V, short circuit current (Isc) of 8.6 µA and charge transfer (Qsc) of 175 nC for Nb2S2C based TENG, and Voc of 127 V, Isc of 9.6 µA, and Qsc of 230 nC for Ta2S2C based TENGs. These two TENGs show a maximum power density of 1360 and 911 mW m−2 respectively. Moreover, the tribology performance is also evaluated with the same materials, revealing that the Ta2S2C/PDMS composite as the electronegative material presented a lower coefficient of friction (COF) than the Nb2S2C/PDMS composite. Their applications for energy harvesting and self‐powered sensing are also demonstrated. [ABSTRACT FROM AUTHOR]

Published
2024
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36. A Pulsed Bubble‐Driven Efficient Liquid‐Solid Triboelectric Nanogenerator.

Author

Liu, Tao, Cui, Xue, Ye, Ziyi, Li, Xuedi, Liu, Yanhua, Luo, Bin, Zhang, Song, Chi, Mingchao, Wang, Jinlong, Cai, Chenchen, Bai, Yayu, Wang, Shuangfei, and Nie, Shuangxi

Subjects
*KINETIC energy, *ENERGY harvesting, *POTENTIAL energy, *ENERGY density, *ELECTRIFICATION, *BUBBLES
Abstract

Harnessing energy from underwater bubbles has garnered significant attention, particularly for powering off‐grid circuitry. However, the efficiency of bubble‐driven liquid‐solid interface charge transfer remains low. This research unveils a phenomenon: accelerated bubble slippage enhances liquid‐solid interfacial charge transfer. Building upon this discovery, a pulse bubble‐based power generation technique is proposed, achieving an energy density of 24.2 mJ L−1 generated by pulsed bubbles. The crux of pulse bubble power generation lies in the precise control of impact velocity. By meticulously regulating the impact kinetic energy of bubbles, the accumulated potential energy of multiple small bubbles is converted into instantaneous pulse kinetic energy. A typical pulse bubble is controlled within a 72 ms timeframe, unleashing a surge of energy that can directly illuminate 400 light‐emitting diodes. This approach represents a groundbreaking advancement in underwater energy harvesting technology, dramatically expanding its potential applications. [ABSTRACT FROM AUTHOR]

Published
2024
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37. Magnetotropic Hybrid Generator with Self‐Switching Mechanism for Long‐Term Forest Fire Prevention.

Author

Zheng, Changyue, Liang, Chuangjian, Wen, Honggui, Qu, Hang, Ning, Heng, Chen, Chunjin, Long, Siyu, Wan, Lingyu, Liu, Guanlin, and Guo, Hengyu

Subjects
*FOREST fire prevention & control, *FIRE alarms, *ENERGY harvesting, *POWER resources, *WIND power
Abstract

The integration of triboelectric nanogenerator (TENG) with electromagnetic generator (EMG) holds promise for the efficient harvesting of broadband wind energy, yet the challenge of coupling these two systems into one high‐durability unit has persisted. Herein, a novel magnetic attraction coupling principle is proposed to enable seamless switching between TENG unit and EMG unit across varying rotation speeds without the need for additional mechanical components, thereby enhancing the energy harvesting efficiency of the magnetotropic hybrid generator (MHG). The rotating magnetic field induces the Si‐Mn steel plates to operate in a contact‐separation mode within a compact space, producing a 270 V open‐circuit voltage output, while the excess magnetic flux is captured by coils to generate an induced current of 5 mA. Most importantly, the overall structure is free from mechanical wear, maintaining consistent performance after 130 000 cycles. The harvested wind energy by MHG is utilized to power human infrared sensors, flame sensors, and Bluetooth hygrometers, providing a long‐term, stable power supply for forest fire early warning systems. This study pioneers a novel and robust mechanism that effectively combines TENG and EMG using magnetotropic property, opening a new avenue for efficiently harvesting wide‐band mechanical energy. [ABSTRACT FROM AUTHOR]

Published
2024
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38. Biowaste‐Derived Triboelectric Nanogenerators for Emerging Bioelectronics.

Author

Bhaduri, Abhisikta and Ha, Tae‐Jun

Subjects
*NANOGENERATORS, *ELECTROSTATIC induction, *ELECTRONIC waste, *MECHANICAL energy, *BIOMEDICAL materials
Abstract

Triboelectric nanogenerators (TENGs) combine contact electrification and electrostatic induction effects to convert waste mechanical energy into electrical energy. As conventional devices contribute to electronic waste, TENGs based on ecofriendly and biocompatible materials have been developed for various energy applications. Owing to the abundance, accessibility, low cost, and biodegradability of biowaste (BW), recycling these materials has gained considerable attention as a green approach for fabricating TENGs. This review provides a detailed overview of BW materials, processing techniques for BW‐based TENGs (BW‐TENGs), and potential applications of BW‐TENGs in emerging bioelectronics. In particular, recent progress in material design, fabrication methods, and biomechanical and environmental energy‐harvesting performance is discussed. This review is aimed at promoting the continued development of BW‐TENGs and their adoption for sustainable energy‐harvesting applications in the field of bioelectronics. [ABSTRACT FROM AUTHOR]

Published
2024
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39. Fabric‐Reinforced Functional Insoles with Superior Durability and Antifracture Properties for Energy Harvesting and AI‐Empowered Motion Monitoring.

Author

Gao, Yuanyuan, Xu, Bingang, Qiu, Minyu, Li, Zhenyu, Ahmed, Taosif, Yang, Yujue, Guan, Xiaoyang, and Fu, Hong

Subjects
*DIGITAL watches, *MACHINE learning, *ENERGY harvesting, *COMPRESSIVE force, *FRACTURE mechanics
Abstract

Functional triboelectric insoles hold promise for advancing self‐powered wearable technologies. However, their durability is compromised by continuous compressive forces and friction, leading to surface abrasion and material fracturing. To address these challenges, an innovative fabric‐reinforced structure combined with a dual‐L backrest design is developed that enhances anti‐fracture capabilities and electric outputs while enabling AI‐empowered motion monitoring. Polydimethylsiloxane (PDMS) is used as the negative triboelectric material with a dual‐L backrest design, while insulated copper wire (icuW) serves as the positive triboelectric material with an annular structure design. These components are intricately nested to enable a multilayered friction pairing. The fabric‐reinforced structure demonstrates excellent compressive rebound resilience, withstanding forces of at least 1000 N. The functional insole, featuring a fabric‐reinforced dual‐L backrest structure (FRdL‐insole), efficiently harvests biomechanical energy with a peak power of 8214 µW and maintains highly consistent performance after 10 washing cycles and 60 000 durability tests. It can power portable electronic devices such as digital watches, calculators, hygrometers, and LEDs. Enhanced with machine learning algorithms, the FRdL‐insole processes sensor signals to monitor human movements, accurately identifying seven distinct motions. This positions the insole as a smart, real‐time, self‐powered tool for activity recognition, showcasing its potential in intelligent wearable technology. [ABSTRACT FROM AUTHOR]

Published
2024
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40. Aluminosilicate-based material fabricated from fly ash for energy harvesting application.

Author

Thongthapthai, Wittawat, Harnchana, Viyada, Sintusiri, Jirapan, Payakaniti, Panjasila, Thongbai, Prasit, and Amornkitbamrung, Vittaya

Subjects
*MECHANICAL energy, *ENERGY harvesting, *FLY ash, *DIELECTRIC properties, *PERMITTIVITY, *ELECTROSTATIC induction
Abstract

A triboelectric nanogenerator (TENG) is an emerging energy harvesting technology that utilizes the combination of triboelectrification and electrostatic induction to collect wasted mechanical energy and convert it into electricity. In this work, an aluminosilicate (AS)-based composite, considered as a potential alternative to cement material, has been developed for the fabrication of TENGs. Herein, the AS material is synthesized through the alkali activation of fly ash using a mixture of sodium hydroxide (NaOH) and sodium silicate (Na 2 SiO 3) solutions as activating agents. The electrical output of AS TENGs can be optimized by tuning the liquid-to-solid powder (L/S) ratio during the fabrication of AS composites. The AS composites fabricated at different L/S ratios exhibit the variations in dielectric properties, surface morphology and microstructure. It is found that a high dielectric constant is not the only requirement for achieving optimal TENG output performance. The contribution of dielectric properties and microstructures of the AS composites on TENG performance is discussed. The AS composite with an optimal L/S ratio of 0.5 results in the highest TENG power output density of 2.78 W/m2. Additionally, the versatility of AS TENG to harvest mechanical energy and its application as a power source for portable electronic device are demonstrated. This research has proposed the promising aspect of AS composites as alternative construction materials capable of harvesting mechanical energy, which is essential for the development of green and sustainable power sources. [ABSTRACT FROM AUTHOR]

Published
2024
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41. High-performance biodegradable triboelectric nanogenerators using CoFe2O4 filled poly (butylene adipate-co-terephthalate).

Author

Kadabahalli Thammannagowda, Vishnu, Guddenahalli Shivanna, Kariyappa Gowda, Ankanahalli Shankaregowda, Smitha, and Kalappa, Prashantha

Subjects
*NANOGENERATORS, *CLEAN energy, *ENERGY harvesting, *TECHNOLOGICAL innovations, *FLEXIBLE electronics, *BIODEGRADABLE nanoparticles
Abstract

The hunt for sustainable and efficient energy harvesting and storage devices has driven significant interest in triboelectric nanogenerators (TENGs) as potential alternatives to traditional batteries for powering electronic devices. However, the development of biodegradable TENGs remains a formidable challenge. This study presents the preparation of a tribopositive material entirely composed of biodegradable poly(butylene adipate-co-terephthalate) (PBAT) polymer enhanced with CoFe2O4 (CF) nanoparticles. The CF nanoparticles, synthesized via the combustion method, were incorporated into the PBAT matrix through solvent casting to form films with varied filler content (0.2, 0.4, 0.6, 0.8, and 1 g). The CF nanoparticles structural, surface, and electrical properties were characterized using XRD and FTIR spectroscopy. At the same time, the morphology of the nanomaterials and their composites was analyzed by scanning electron microscopy. Specifically, the 0.8 g PBAT-CF TENG demonstrated superior performance, achieving an output voltage of 45.45 V and a current of 4.5 µA. Subsequent electrical studies, including charging commercial capacitors (1.0 to 47 μF) and powering LEDs and calculators, underscored the device's efficiency. The PBAT-CF TENG also effectively generated voltage and current signals from physical activities like walking and jumping. This innovative approach highlights the potential for biodegradable, high-performing, self-powered flexible electronics, and wearable devices, paving the way for sustainable technological advancements. [ABSTRACT FROM AUTHOR]

Published
2024
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42. Unlocking multidirectional and broadband wind energy harvesting with triboelectric nanogenerator and vortex-induced vibration of sphere.

Author

Zhang, Lanbin, He, Yixiang, Meng, Bo, Dai, Huliang, and Wang, Lin

Subjects
*NANOGENERATORS, *ENERGY harvesting, *WIND power, *SPHERES, *SPEED, *WIND speed
Abstract

A unique oscillating wind-driven triboelectric nanogenerator (OWTENG) based on the sphere's vortex-induced vibration (VIV) behavior is proposed in this study, which can harvest wind energy across a multitude of horizontal directions. With the Euler-Lagrange method, the coupled governing equations of the OWTENG are established and subsequently validated by experimental tests. The vibrational properties and output performance of the OWTENG for varying wind speeds are analyzed, demonstrating its effectiveness in capturing wind energy across a broad range of wind speeds (from 2.20 m/s to 8.84 m/s), and the OWTENG achieves its peak output power of 106.3 µW at a wind speed of 5.72 m/s. Furthermore, the OWTENG maintains a steady output power across various wind directions within the speed range of 2.20 m/s to 7.63 m/s. Nevertheless, when the wind speed exceeds 7.63 m/s, the vibrational characteristics of the sphere shift based on the wind direction, leading to fluctuations in the OWTENG's output power. This research presents an innovative approach for designing vibrational triboelectric nanogenerators, offering valuable insights into harvesting wind energy from diverse directions and speeds. [ABSTRACT FROM AUTHOR]

Published
2024
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43. Advances in Wearable Multifunctional Devices Based on Human‐Body Energy Harvesting.

Author

Chu, Huaqing, Xue, Jiangtao, Luo, Dan, Zheng, Hui, and Li, Zhou

Subjects
*WEARABLE technology, *ENERGY harvesting, *POWER resources, *ELECTRONIC equipment, *ARTIFICIAL intelligence
Abstract

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. [ABSTRACT FROM AUTHOR]

Published
2024
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44. High-performance triboelectric nanogenerator based on biocompatible electrospun polycaprolactone nanofiber and counter convex PDMS for low-frequency mechanical energy harvesting.

Author

Nguyen, Vu Viet Linh, Vu, Thi Kieu Tien, Huynh, Dai Phu, and Bui, Van-Tien

Subjects
*NANOGENERATORS, *MECHANICAL energy, *ENERGY harvesting, *OPEN-circuit voltage, *SHORT-circuit currents, *POLYCAPROLACTONE
Abstract

Triboelectric nanogenerators (TENGs) made from biocompatible materials serve as promising integrated power sources for portable wearable electronics due to many advantages such as lightweight, high flexibility, simple technique, and excellent breathability. In this work, we report the fabrication of electrospun polycaprolactone micro-nanofiber films (s-PCL) and convex-microdome-patterned polydimethylsiloxane (c-PDMS) utilizing electrospinning and micromolding techniques. These materials, s-PCL and c-PDMS, are utilized as positively and negatively charged tribosurfaces, respectively, in the development of a bioTENG device. The developed TENG device can generate a superior power output of 2 mW with an open-circuit voltage (VOC) of 188 V and short-circuit current (ISC) of 18.5 µA, even under a low triggering frequency of 5 Hz. In addition, TENG possesses outstanding durability and output performance stability over a continuous operation of nearly 16,000 cycles. Furthermore, the TENG demonstrates its capacity to harvest mechanical energy and convert it into electricity, capable of directly illuminating more than 100 LEDs. The electrospun s-PCL- and c-PDMS-based TENG can be considered for self-powdered wearable devices attached to fingers, wrists, feet, and other human body parts. [ABSTRACT FROM AUTHOR]

Published
2024
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45. Achieving Ultrahigh Efficiency of Triboelectric Nanogenerator Energy Harvesting Systems via Hybrid Electronic‐Spark Power Management.

Author

Liufu, Yong Hong, Tse, Chi K., Yang, Guiyuan, Liao, Yining, Lin, Hongjian, Dai, Dong, Lin, Han, Hong, Hongxin, Wu, Hao, and Zhang, Xuexia

Subjects
*ENERGY harvesting, *ELECTRIC breakdown, *BREAKDOWN voltage, *HYBRID power, *POWER density
Abstract

Significant efforts are devoted to optimizing the efficiency of triboelectric energy harvesting systems, particularly through the design of an advanced power management system (PMS) for Triboelectric Nanoenerators (TENGs). A critical aspect of PMS is the design and control of switches. However, existing switches face significant limitations. For spark switches, precise control cannot be achieved, and electronic switches can only operate at voltages below several hundred volts which is limited by the risk of electrical breakdown. To address these limitations, a hybrid electronic‐spark switch power management system (HESS) is proposed. HESS changes the connection of capacitors from parallel to series by deploying a maximum voltage tracking switch components at the peak voltage point, resulting in a much‐elevated voltage level to activate the spark switch. This approach achieves precise control of the spark switch for the first time and significantly reduces the operating voltage of electronic switches. Through simulation and experimental verification, HESS achieves the control at a voltage level of 1.8 kV for spark switch, with an electrical component breakdown voltage of only 450 V. The power density of the HESS is 29.8 mW Hz−1 m−2, which is a new record for electronic switches. [ABSTRACT FROM AUTHOR]

Published
2024
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46. Enhancing Power Generation in Triboelectric Nanogenerators via Integration of Graphene Nanoplatelets and Polyvinyl Alcohol.

Author

Okbaz, Abdulkerim, Yar, Adem, Karabiber, Abdulkerim, Lin, Geng-Sheng, Tong, Zhaohui, and Saeed, Muhammad Ahsan

Subjects
*ENERGY harvesting, *NANOGENERATORS, *MECHANICAL energy, *POWER resources, *ELECTRICAL energy, *TRIBOELECTRICITY
Abstract

Triboelectric nanogenerators (TENGs) provide promising power supply solutions by transforming mechanical energy into electrical energy. However, enhancing electrical performance of TENGs is essential for their widespread practical applications and commercialization. In this study, we fabricated TENGs in vertical contact‐separation mode using a tribopositive material—polyvinyl alcohol (PVA) slime—which is biocompatible, flexible, and wearable, decorated with graphene nanoplatelets (GnPs), and paired with tribonegative silicone. We analyzed the correlation between the electrical performance of the TENGs and the inherent triboelectric properties of the constituent material, including the evaluation of surface roughness, the measurement of the contact potential difference (CPD), and the material's dielectric constant. The incorporation of GnPs increased the dielectric constant of the composite material and its electron‐donating tendency, thus, increasing the contact potential difference. The GnPs concentration of 1 wt% was identified as the optimal value, resulting in a 42% increase in power density. The 1 wt% GnPs@PVA&Silicone TENG exhibited an open‐circuit voltage of 718 V and a peak power density of 15.3 W/m2. This study sheds light on enhancing the energy harvesting efficiency of TENGs through the utilization of biocompatible tribopositive and tribonegative materials. [ABSTRACT FROM AUTHOR]

Published
2024
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47. Multimodal Intelligent Flooring System for Advanced Smart‐Building Monitoring and Interactions.

Author

Chen, Yuqi, Hong, Jianlong, Xiao, Yukun, Zhang, Huiyun, Wu, Jun, and Shi, Qiongfeng

Subjects
*NANOGENERATORS, *PRESSURE sensors, *DIGITAL twins, *ENERGY harvesting, *INTELLIGENT buildings
Abstract

The floor constitutes one of the largest areas within a building with which users interact most frequently in daily activities. Employing floor sensors is vital for smart‐building digital twins, wherein triboelectric nanogenerators demonstrate wide application potential due to their good performance and self‐powering characteristics. However, their sensing stability, reliability, and multimodality require further enhancement to meet the rapidly evolving demands. Thus, this work introduces a multimodal intelligent flooring system, implementing a 4 × 4 floor array for multimodal information detection (including position, pressure, material, user identity, and activity) and human–machine interactions. The floor unit incorporates a hybrid structure of triboelectric pressure sensors and a top‐surface material sensor, facilitating linear and enhanced sensitivity across a wide pressure range (0–800 N), alongside the material recognition capability. The floor array is implemented by an advanced output‐ratio method with minimalist output channels, which is insensitive to environmental factors such as humidity and temperature. In addition to multimodal sensing, energy harvesting is co‐designed with the pressure sensors for scavenging waste energy to power smart‐building sensor nodes. This developed flooring system enables multimodal sensing, energy harvesting, and smart‐sport interactions in smart buildings, greatly expanding the floor sensing scenarios and applications. [ABSTRACT FROM AUTHOR]

Published
2024
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48. Hybrid Triboelectric‐Electromagnetic‐Electric Field Energy Harvester for Simultaneous Wind and Electric Field Energy Capture in High‐Voltage Transmission System.

Author

Wang, Qianwang, Hu, Dongyang, Huang, Xiaolong, Chen, Zehong, Yuan, Zitang, Zhong, Lipeng, Sun, Qiuqin, Wang, Feng, Xu, Sixing, and Chen, She

Subjects
*POWER resources, *NANOGENERATORS, *ELECTROMAGNETIC waves, *ELECTRIC fields, *ENERGY consumption, *ENERGY harvesting
Abstract

With the development of smart grids, efficient condition monitoring of high voltage transmission system has become crucial, necessitating reliable power supplies for distributed sensors. Traditional energy harvesters often focus on either internal or external sources, limiting overall efficiency. This study introduces a triboelectric‐electromagnetic‐electric field hybrid energy harvester (TEE‐HEH) that synergistically integrates triboelectric nanogenerators (TENGs), electromagnetic generators (EMGs), and electric field energy harvesters (EEHs) to simultaneously capture electric field and wind energy. Electric field energy is harvested via displacement currents between transmission lines and the ground, while TENGs and EMGs efficiently capture low‐ and high‐speed wind energy, respectively, enabling broadband harvesting (2.3–10 m s−1). The synergistic combination of TENG, EMG, and EEH within the TEE‐HEH leads to significantly enhanced energy capture efficiency from multiple sources. At a wind speed of 5 m s−1, a transmission line voltage of 25 kV, and a distance of 1.5 m, the TEE‐HEH achieved peak power outputs of 18.5 mW (TENG), 262 mW (EMG), and 1.85 mW (EEH), demonstrating enhanced energy collection efficiency. An environmental monitoring system has been powered, demonstrating the TEE‐HEH's practicality for dual‐source energy harvesting in smart grid applications. [ABSTRACT FROM AUTHOR]

Published
2024
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49. Synergistic energy harvesting and humidity sensing with single electrode triboelectric nanogenerator.

Author

Behera, Swayam Aryam, Hajra, Sugato, Panda, Swati, Sahu, Alok Kumar, Alagarsamy, Perumal, Mishra, Yogendra Kumar, Kim, Hoe Joon, and Achary, P. Ganga Raju

Subjects
*NANOGENERATORS, *ENERGY harvesting, *BISMUTH iron oxide, *FOOD industry, *TRIBOELECTRICITY, *SOL-gel processes
Abstract

Humidity sensors using triboelectric nanogenerators (TENGs) technology can provide continuous operation without the need for additional batteries. These sensors provide sustainable and self-powered humidity monitoring solutions, that can be utilized in various agriculture platforms and food processing industries. In this work, a sol-gel method is utilized to process the bismuth ferrite (abbreviated as BFO) materials and a simple mould pressing method to obtain freestanding Ethylene-vinyl acetate (abbreviated EVA)-BFO composites. These composites were characterized to shed light upon structural and microstructural properties. The single electrode mode operating TENG was fabricated having 2 cm × 2 cm active area at various wt.% of BFO onto EVA-based composites to compare the electrical response. The 5 wt.% BFO-EVA-based composites/FEP-based TENG generates a voltage and current of 45 V and 800 nA. Further, the TENG device was tested for long-term stability for 400 s, and charging of various capacitors having capacitance values such as 0.1 μF, 1 μF, 4.7 μF, and 10 μF along with 3 times charging/discharging cycles of 0.1 μF capacitor have been demonstrated. The humidity sensing mechanism elucidated which follows the conduction process based on the Grotthuss proton hopping mechanism. The TENG demonstrates a sensitivity of 0.53 V/RH% over the relative humidity range from 25 % to 85 %. The powering of the wristwatch confirms that fabricated TENG can be a reliable power source for future low-power electronics. [ABSTRACT FROM AUTHOR]

Published
2024
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50. A Kelp Inspired High‐Power Density Triboelectric Nanogenerator with Stacking Structure for Multiple Directional Ocean Wave Energy Harvesting.

Author

Sun, Chao, Liu, Xue, Zhong, Wei, Pan, Qinying, Chen, Longyi, Zhang, Gengchen, Wang, Jia, Dong, Xiaohong, and Shao, Jiang

Subjects
*OCEAN waves, *WAVE energy, *ENERGY harvesting, *CLEAN energy, *DIGITAL watches
Abstract

Ocean wave energy is one of the most promising green energies in the wild. However, it is still challenging to effectively collect wave energy due to its randomness and irregularity. In this work, a kelp inspired high‐power density triboelectric nanogenerator (K‐TENG) is presented for harvesting wave energy with characteristics in multiple directions. The proposed K‐TENG consists of a series of stacked leaf‐like units. The influence of configuration parameters, including pellet diameters, pellet numbers, unit sizes, oscillation frequency, swing amplitude, and wave directions on output performances of leaf‐like units, are extensively investigated. Experimental data indicates that a single leaf‐like unit can achieve a maximum output voltage of 623.14 V as well as a maximum current of 1.48 µA and realize energy harvesting from different wave directions. A K‐TENG composed of 15 leaf‐like units demonstrates a high‐power density of 18.77 W m−3 at a wave frequency of 2.5 Hz, which successfully powers a digital watch and 414 light‐emitting diodes (LEDs). This work is hoped to provide a simple and reliable route to effectively harvest ocean wave energy. [ABSTRACT FROM AUTHOR]

Published
2024
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