Academic Talk:Ultralight Triboelectric Nanogenerators for Portable Self-charging Power Unit and Self-powered Sensing Platform


Presenter:Prof. Min-Hsin Yeh

Topc:Ultralight Triboelectric Nanogenerators for Portable Self-charging Power Unit and Self-powered Sensing Platform

Time:10:00 AM, May 20th (Monday)



With rapid development of portable electronic devices and systems, mandatory requirements of portable, lightweight, and significantly sustainable power sources have attracted huge attention. Li-ion batteries or other energy storage devices are commonly used as a stable power supply for driving these electronic devices with small-scale energy consumption at the μW to mW level. Nevertheless, in modern personal electronics, batteries are usually the largest or heaviest component in the whole device, and moreover, the crucial problem of batteries is their limited lifetime and thus their need to be charged or replaced frequently. To conquer this problem, self-powered systems as integrated by an energy harvester and an energy storage device has been proposed and developed to simultaneously harvest and store ambient energy in the form of electricity, which opens potentials for sustainable and maintenance-free applications. Here, we report a ultralight cut-paper-based self-charging power unit (PC-SCPU) that is capable of simultaneously harvesting and storing energy from body movement by combining a paper-based triboelectric nanogenerator (TENG) and a supercapacitor (SC), respectively. Utilizing the paper as the substrate with an assembled cut-paper architecture, an ultralight rhombicshaped TENG is achieved with highly specific mass/volume charge output (82 nC g?1/75 nC cm?3) compared with the traditional acrylic-based TENG (5.7 nC g?1/5.8 nC cm?3), which can effectively charge the SC (1 mF) to 1 V in minutes. PC-SCPU is demonstrated as a sustainable power source for driving wearable and portable electronic devices such as a wireless remote control. To further enhance the output performance of TENG for extending the possible applications in portable electronic devices, we also report an ultrahigh output power of whirligig-inspired TENG (Wi-TENG) designed according to an antiqueue whirligig toy that is capable of converting low-frequency pulling motion into a high-frequency rotation. It shows that the rotor in the Wi-TENG achieves a maximum speed of 11,250 rpm. Ultrahigh charge transfer quantity of ~310 μC and output power of 40.18mW are obtained by per pulling of Wi-TENG. Moreover, a maximum short circuit current of 317 μA and a constant open-circuit voltage peak value of 153 V can be generated by the Wi-TENG, which can rapidly charge a commercial capacitance (100 μF) to ~14 V within 10 s. After power management, this Wi-TENG is successfully demonstrated as a portable sustainable power source for driving a commercial blood glucose meter.


Prof. Min-Hsin Yeh received his B. Sc. and M. Sc. degrees in Department of Chemical Engineering from National Taiwan University of Science and Technology (Taiwan Tech) in 2007 and 2009, respectively, and Ph.D. degree in Department of Chemical Engineering from National Taiwan University (NTU) under the supervision of Prof. Kuo-Chuan Ho in 2013. He then performed as a postdoctoral research fellow at the School of Materials Science and Engineering in Georgia Institute of Technology with Prof. Zhong Lin Wang’s research group (2014~2016). Currently, he is an Assistant Professor in Department of Chemical Engineering of National Taiwan University of Science & Technology (Taiwan Tech) since 2018. His research interests are focused in the area of the nanomaterials and their applications in electrochemistry, photoelectrochemistry, energy harvesting systems, energy storage devices, and self-powered systems. He is also interested in the development and application of synchrotron radiation techniques and in-situ analytical techniques in nanomaterials study. He has published over 70 papers (Average IF=8.666, h-index=34; Citations ~2,800) in high impact journals such as Sci. Adv., Adv. Mater., Adv. Energy Mater., Adv. Fun. Mater., ACS Nano, Nano Energy, etc.


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