Your search keyword '"Pang, Yaokun"' showing total 12 results

1. Tribotronic transistor sensor for enhanced hydrogen detection

Author

Pang, Yaokun, Chen, Libo, Hu, Guofeng, Luo, Jianjun, Yang, Zhiwei, Zhang, Chi, and Wang, Zhong Lin

Published

2017

2. Marine biomaterial-based triboelectric nanogenerators: Insights and applications.

Author

Li, Yunmeng, Liu, Xin, Ren, Zewei, Luo, Jianjun, Zhang, Chi, Cao, Changyong (Chase), Yuan, Hua, and Pang, Yaokun

Abstract

The push for green and eco-friendly materials has intensified, driven by the mounting environmental concerns associated with traditional petroleum-based products. As land resources shrink and space for development narrows, marine biomaterials have emerged as a promising alternative over the past decades. Well-known for their vast availability, outstanding biocompatibility, impressive biodegradability, and minimal toxicity, marine biomaterials present an ideal foundation for developing eco-friendly triboelectric nanogenerators (TENGs). In this review, we present the evolution of TENGs based on marine biomaterials, from their core working principles to their multifaceted applications. We begin by elucidating the operational modes and foundational principles of TENGs. Next, we highlight the intrinsic qualities and advantages of marine biomaterials commonly utilized in TENG designs. Additionally, we discuss approaches adopted to amplify the efficacy of TENGs derived from marine biomaterials. A synthesis of documented applications of these TENGs from existing literature is then presented. We finally discuss the existing challenges and future directions in marine biomaterial-inspired TENGs. [Display omitted] • Intensively introduces the intrinsic qualities and advantages of marine biomaterials commonly utilized in TENG designs. • Systematically reviews the approaches adopted to amplify the efficacy of TENGs derived from marine biomaterials. • Comprehensively summarizes the applications of marine biomaterial-based TENG from existing literature. • We discuss the existing challenges and future directions in marine biomaterial-inspired TENGs. [ABSTRACT FROM AUTHOR]

Published

2024

3. Self-powered intelligent buoy system by water wave energy for sustainable and autonomous wireless sensing and data transmission.

Author

Xi, Fengben, Pang, Yaokun, Liu, Guoxu, Wang, Shuwei, Li, Wei, Zhang, Chi, and Wang, Zhong Lin

Abstract

Harvesting ocean wave energy is a killer application of triboelectric nanogenerator (TENG) for advantages in simple mechanism, high power density and high efficiency at low frequency. Here we report a self-powered intelligent buoy system (SIBS), in which a high-output multilayered TENG is used for water wave energy harvesting. With a power management module, the output voltage can be converted and regulated as a steady DC voltage of 2.5 V for the operations of a microprogrammed control unit (MCU), several micro sensors and a transmitter. With the intelligent monitoring mechanism of the MCU, the harvested energy can be deployed for each sensor with different priority and data transmission cycle, and the SIBS can be at standby and active status by itself at different energy levels. At a wave frequency of 2 Hz, the SIBS can provide an average output power density of 13.2 mW/m2 and realize sustainable and autonomous wireless sensing for acceleration, magnetic intensity and temperature in range of 15 m, with amount of 19 bytes every 30 s. The SIBS has first demonstrated a complete TENG-based micro-energy solution for self-powered intelligent system, including energy harvesting, management, deployment and utilization, with an unattended manner and infinite lifetime. As a significant milestone for the TENG, this work has provided a universal platform for self-powered wireless sensor network nodes and exhibited broad prospects in internet of things, big data, artificial intelligence and blue energy. We propose a self-powered intelligent buoy system (SIBS), including a high-output multilayered TENG for harvesting water wave energy, which can be used for sustainable and autonomous wireless sensing and data transmission. Image 1 • A self-powered intelligent buoy system (SIBS) is proposed, in which a high-output multilayered TENG is used for water wave energy harvesting. • With a power management module, the output voltage can be converted and regulated as a steady DC voltage of 2.5 V for the operations of a microprogrammed control unit (MCU), several micro sensors and a transmitter. • With the intelligent monitoring mechanism of the MCU, the harvested energy can be deployed for each sensor with different priority and data transmission cycle, and the SIBS can be at standby and active status by itself at different energy levels. • This work has provided a universal platform for TENG-based self-powered wireless sensor network nodes and exhibited broad prospects in internet of things, big data, artificial intelligence and blue energy. [ABSTRACT FROM AUTHOR]

Published

2019

4. Torus structured triboelectric nanogenerator array for water wave energy harvesting.

Author

Liu, Wenbo, Xu, Liang, Bu, Tianzhao, Yang, Hang, Liu, Guoxu, Li, Wenjian, Pang, Yaokun, Hu, Chuxiong, Zhang, Chi, and Cheng, Tinghai

Abstract

Abstract Water wave energy is regarded as one of the most prospective renewable energy sources, while most of it has not been utilized for numerous technology defects. As a new energy technology, triboelectric nanogenerator (TENG) has been widely utilized for low frequency and random mechanical energy harvesting, which is very suitable for scavenging water wave energy. In this paper, we present a torus structured triboelectric nanogenerator (TS-TENG) which consists of an inner ball and a torus shell. Triggered by water waves, the ball revolves in the torus shell for triboelectric power generation, and the TS-TENG can harvest random wave energy from all directions. Moreover, to scavenge large-scale water wave energy, the TS-TENG array is fabricated and presented as a power source for persistently powering electronic devices and charging a battery or capacitor. With an agitation frequency of 2 Hz and an oscillation angle of 5°, the TS-TENG is expected to give a maximum peak power density of 0.21 W/m2. Take advantage of low-cost, environment-friendly and easy- implement, the development of the TS-TENG is of great significance for harvesting large-scale ocean wave energy and other potential applications in blue energy. Graphical abstract Triggered by water waves, the inner ball revolves in the torus shell for triboelectric power generation, and the TS-TENG can harvest random wave energy from all directions. Moreover, to scavenge large-scale water wave energy, the TS-TENG array is fabricated and presented as a power source for persistently powering electronic devices and charging a battery or capacitor. fx1 Highlights • A torus structured triboelectric nanogenerator (TS-TENG) which encloses an inner ball inside a torus shell is investigated. • Triggered by water waves, the ball revolves in the torus shell for triboelectric power generation, and the TS-TENG can harvest random wave energy from all directions. • The TS-TENG array is fabricated and demonstrated as a power source for continuously driving electronic devices and charging an energy storage unit. • With an agitations frequency of 2 Hz and an oscillation angle of 5°, the TS-TENG is expected to give a maximum peak power density of 0.21 W/m2. [ABSTRACT FROM AUTHOR]

Published

2019

5. Self‐Powered Hall Vehicle Sensors Based on Triboelectric Nanogenerators.

Author

Guo, Tong, Zhao, Junqing, Liu, Wenbo, Liu, Guoxu, Pang, Yaokun, Bu, Tianzhao, Xi, Fengben, Zhang, Chi, and Li, Xinjian

Subjects

TRIBOELECTRICITY, ELECTROSTATICS, SURFACE charging, ELECTRONIC equipment, AUTOMOBILE industry

Abstract

Abstract: Growing demand in automobile safety system raises a requirement to electronic devices being self‐powered, stable, and durable. Herein, a self‐powered Hall vehicle sensor (SPHVS) is demonstrated for automobile safety system, which integrates the triboelectric nanogenerator, the management circuit, the magnet, and the Hall element. The tribotronic constant current source is proposed to steadily power the Hall element in rotational motion at any different speeds. Furthermore, the performances of the SPHVS for vehicle speed sensing and vehicle braking monitoring are systematically investigated, which exhibits wide sensing range, great stability, and excellent sensitivity. This work clearly proposes a promising solution for speed sensing and braking monitoring, and indicates the potential applications of power tribotronics for the self‐powered electronic devices in prospective automobile industry. [ABSTRACT FROM AUTHOR]

Published

2018

6. Efficient Storing Energy Harvested by Triboelectric Nanogenerators Using a Safe and Durable All-Solid-State Sodium-Ion Battery.

Author

Hou, Huidan, Xu, Qingkai, Pang, Yaokun, Li, Lei, Wang, Jiulin, Zhang, Chi, and Sun, Chunwen

Published

2017

7. Universal power management strategy for triboelectric nanogenerator.

Author

Xi, Fengben, Pang, Yaokun, Li, Wei, Jiang, Tao, Zhang, Limin, Guo, Tong, Liu, Guoxu, Zhang, Chi, and Wang, Zhong Lin

Abstract

Effective power management has always been the difficulty and bottleneck for practicability of triboelectric nanogenerator (TENG). Here we propose a universal power management strategy for TENG by maximizing energy transfer, direct current (DC) buck conversion, and self-management mechanism. With the implemented power management module (PMM), about 85% energy can be autonomously released from the TENG and output as a steady and continuous DC voltage on the load resistance. The DC component and ripple have been systematically investigated with different circuit parameters. At a low frequency of 1 Hz with the PMM, the matched impedance of the TENG has been converted from 35 MΩ to 1 MΩ at 80% efficiency, and the stored energy has been dramatically improved in charging a capacitor. The universality of this strategy has been greatly demonstrated by various TENGs with the PMM for harvesting human kinetic and environmental mechanical energy. The universal power management strategy for TENG is promising for a complete micro-energy solution in powering wearable electronics and industrial wireless networks. With the new coupling mode of triboelectricity and semiconductor in the PMM, the tribotronics has been extended and a new branch of power-tribotronics is proposed for manageable triboelectric power by electronics. [ABSTRACT FROM AUTHOR]

Published

2017

8. Tribotronic Enhanced Photoresponsivity of a MoS2 Phototransistor.

Author

Pang, Yaokun, Xue, Fei, Wang, Longfei, Chen, Jian, Luo, Jianjun, Jiang, Tao, Zhang, Chi, and Wang, Zhong Lin

Published

2016

9. Efficient Charging of Li‐Ion Batteries with Pulsed Output Current of Triboelectric Nanogenerators.

Author

Pu, Xiong, Liu, Mengmeng, Li, Linxuan, Zhang, Chi, Pang, Yaokun, Jiang, Chunyan, Shao, Lihua, Hu, Weiguo, and Wang, Zhong Lin

Abstract

The triboelectric nanogenerator (TENG) is a promising mechanical energy harvesting technology, but its pulsed output and the instability of input energy sources make associated energy‐storage devices necessary for real applications. In this work, feasible and efficient charging of Li‐ion batteries by a rotating TENG with pulsed output current is demonstrated. In‐depth discussions are made on how to maximize the power‐storage efficiency by achieving an impedance match between the TENG and a battery with appropriate design of transformers. With a transformer coil ratio of 36.7, ≈72.4% of the power generated by the TENG at 250 rpm can be stored in an LiFePO4–Li4Ti5O12 battery. Moreover, a 1 h charging of an LiCoO2–C battery by the TENG at 600 rpm delivers a discharge capacity of 130 mAh, capable of powering many smart electronics. Considering the readily scale‐up capability of the TENG, promising applications in personal electronics can be anticipated in the near future. [ABSTRACT FROM AUTHOR]

Published

2016

10. Strategies for effectively harvesting wind energy based on triboelectric nanogenerators.

Author

Ren, Zewei, Wu, Liting, Pang, Yaokun, Zhang, Weiqiang, and Yang, Rusen

Abstract

Wind energy has played a reasonable proportion in the current energy structure, extracting energy from wind sources attracts extensive attention in the era of global carbon neutrality. However, traditional wind turbine based on electromagnetic generator are not economic in some cases, the new technology demand for complementing conventional approaches is proposed. Recently, the emerging triboelectric nanogenerator (TENG) technology based on the coupling of contact electrification and electrostatic induction have been widely researched and utilized to scavenge wind energy, with the advantages of high efficiency, low cost and portability. Here, the recent advances of wind harvesters based on TENG are reviewed, where the material, structure design, power management and the developed strategies to optimize the performance of TENG-based wind harvesting system are summarized. Meanwhile, the hybridization of TENG with other types of energy harvesting techniques is discussed. Finally, the application, outlook and challenge in the growth of TENG-based wind harvester are outlined. Here, the recent advances of wind harvesters based on triboelectric nanogenerators (TENG) are reviewed. The Strategies to improve the performance of wind driven TENG (WD-TENG) from the perspectives of material, structure optimization and power management are demonstrated. Meanwhile, the applications and development trend of WD-TENG are proposed. [Display omitted] • Strategies to improve performance of WD-TENG from aspects of material, structure and power management are demonstrated. • The hybridization between TENG and other technologies for developing compound wind energy harvesters are demonstrated. • The applications of WD-TENG are discussed, including powering portable electric devices, sensing system, etc. • The existing challenges and trend of development of WD-TENG in the future are proposed. [ABSTRACT FROM AUTHOR]

Published

2022

11. Automobile Safety Systems: Self‐Powered Hall Vehicle Sensors Based on Triboelectric Nanogenerators (Adv. Mater. Technol. 8/2018).

Author

Guo, Tong, Zhao, Junqing, Liu, Wenbo, Liu, Guoxu, Pang, Yaokun, Bu, Tianzhao, Xi, Fengben, Zhang, Chi, and Li, Xinjian

Subjects

TRIBOELECTRICITY, ELECTROSTATICS

Abstract

The front cover page of the journal is presented.

Published

2018

12. Biodegradable, transparent, and antibacterial alginate-based triboelectric nanogenerator for energy harvesting and tactile sensing.

Author

Li, Yunmeng, Chen, Shoue, Yan, Hao, Jiang, Haowen, Luo, Jianjun, Zhang, Chi, Pang, Yaokun, and Tan, Yeqiang

Subjects

*ENERGY harvesting, *TACTILE sensors, *MECHANICAL energy, *HUMAN mechanics, *SODIUM alginate

Abstract

• A biodegradable, transparent, and antibacterial sodium alginate-based triboelectric nanogenerator is proposed. • A vacuum filtration method was used for preparing patterned transparent conductive sodium alginate/AgNWs electrodes. • Sodium alginate/glycerol substrate have good adhesion to realize the complete transfer of the AgNWs pattern. • The triboelectric nanogenerator has been used as a self-powered tactile sensor. The utilization of natural biomaterials in the construction of triboelectric nanogenerators (TENG) has significant implications for the advancement of sustainable self-powered devices. Sodium alginate (SA), an eco-friendly and biodegradable triboelectric material with excellent transparency, is considered an ideal material for wearable TENGs. In this work, we report a biodegradable, transparent, and antibacterial SA-based TENG for mechanical energy harvesting and self-powered tactile sensing. The addition of glycerol, an environment-friendly additive, can enhance flexibility and adhesiveness of the SA, which resulted in well-transferred AgNWs/SA electrodes with high transparency and conductivity. The major parameters that affect the output performance of the fabricated TENG are investigated, including the frequency, thickness and area of the triboelectric layers. The output voltage, transferred charge, and peak power of the TENG could reach up to 53 V, 18 nC, and 4 μW, respectively, which is sufficient to power small electronic devices. In addition, the fabricated TENG device also shows excellent antibacterial and biodegradable capabilities. Finally, the TENG is demonstrated to be an effective self-powered tactile sensor for pressure mapping, human movement monitoring, and wearable human–machine interfacing. This work provides a new strategy to design flexible transparent TENGs with biodegradable SA and paves the way for developing next-generation self-powered transient electronics. [ABSTRACT FROM AUTHOR]

Published

2023