Access the full text.
Sign up today, get DeepDyve free for 14 days.
Wanghuai Xu, Huanxi Zheng, Yuan Liu, Xiaofeng Zhou, Chao Zhang, Yuxin Song, Xuetao Deng, M. Leung, Zhengbao Yang, Ronald Xu, Zhong Wang, X. Zeng, Zuankai Wang (2020)
A droplet-based electricity generator with high instantaneous power densityNature, 578
Yunlong Zi, Hengyu Guo, Zhen Wen, Min-Hsin Yeh, Chenguo Hu, Zhong Wang (2016)
Harvesting Low-Frequency (<5 Hz) Irregular Mechanical Energy: A Possible Killer Application of Triboelectric Nanogenerator.ACS nano, 10 4
Kar Munirathinam, Dong-Su Kim, A. Shanmugasundaram, Jongsung Park, Y. Jeong, Dong-weon Lee (2022)
Flowing water-based tubular triboelectric nanogenerators for sustainable green energy harvestingNano Energy
P. Veers, K. Dykes, E. Lantz, Stephan Barth, C. Bottasso, O. Carlson, A. Clifton, Johney Green, P. Green, H. Holttinen, D. Laird, Ville Lehtomäki, J. Lundquist, J. Lundquist, J. Manwell, M. Marquis, C. Meneveau, P. Moriarty, X. Munduate, M. Muskulus, J. Naughton, L. Pao, J. Paquette, J. Peinke, A. Robertson, J. Rodrigo, A. Sempreviva, J. Smith, A. Tuohy, R. Wiser (2019)
Grand challenges in the science of wind energyScience, 366
S. Chu, A. Majumdar (2012)
Opportunities and challenges for a sustainable energy futureNature, 488
Jian Yu, Enze Ma, T. Ma (2017)
Harvesting energy from low-frequency excitations through alternate contacts between water and two dielectric materialsScientific Reports, 7
Zhong Wang (2017)
On Maxwell's displacement current for energy and sensors: the origin of nanogeneratorsMaterials Today, 20
Haojie Gu, Nan Zhang, Zhiyuan Zhou, Shi-Zhong Ye, Wenjie Wang, Wanghuai Xu, Huanxi Zheng, Yuxin Song, J. Jiao, Zuankai Wang, Xiaofeng Zhou (2021)
A bulk effect liquid-solid generator with 3D electrodes for wave energy harvestingNano Energy, 87
Xiaolong Zhang, Youbin Zheng, Daoai Wang, Feng Zhou (2017)
Solid-liquid triboelectrification in smart U-tube for multifunctional sensorsNano Energy, 40
G. Zhu, Yuanjie Su, Peng Bai, Jun Chen, Qingshen Jing, Weiqing Yang, Zhong Wang (2014)
Harvesting water wave energy by asymmetric screening of electrostatic charges on a nanostructured hydrophobic thin-film surface.ACS nano, 8 6
Nan Zhang, Huimin Zhang, Wanghuai Xu, Haojie Gu, Shi-Zhong Ye, Huanxi Zheng, Yuxin Song, Zuankai Wang, Xiaofeng Zhou (2022)
A droplet‐based electricity generator with ultrahigh instantaneous output and short charging timeDroplet
Chaowei Wang, Liang Yang, Yanlei Hu, Shenglong Rao, Yulong Wang, Deng Pan, Shengyun Ji, Chenchu Zhang, Yahui Su, Wulin Zhu, Jiawen Li, Dong Wu, J. Chu (2019)
Femtosecond Mathieu Beams for Rapid Controllable Fabrication of Complex Microcages and Application in Trapping Microobjects.ACS nano, 13 4
Zhong Wang, Jinhui Song (2006)
Piezoelectric Nanogenerators Based on Zinc Oxide Nanowire ArraysScience, 312
J. Kaldellis, D. Zafirakis (2011)
The wind energy (r)evolution: A short review of a long historyRenewable Energy, 36
J. Isaacs, W. Schmitt (1980)
Ocean Energy: Forms and ProspectsScience, 207
Xiaolong Zhang, Yang Dong, Xiang Xu, H. Qin, Daoai Wang (2021)
A new strategy for tube leakage and blockage detection using bubble motion-based solid-liquid triboelectric sensorScience China Technological Sciences, 65
F. Fan, Z. Tian, Zhong Wang (2012)
Flexible triboelectric generatorNano Energy, 1
Zhong Wang (2017)
Catch wave power in floating netsNature, 542
E. Stokstad (2016)
RENEWABLE ENERGY. A reboot for wave energy.Science, 352 6286
Hao Wu, Steven Wang, Zuankai Wang, Yunlong Zi (2021)
Achieving ultrahigh instantaneous power density of 10 MW/m2 by leveraging the opposite-charge-enhanced transistor-like triboelectric nanogenerator (OCT-TENG)Nature Communications, 12
Nan Zhang, Haojie Gu, Huanxi Zheng, Shi-Zhong Ye, Ling Kang, Chun Huang, Keyu Lu, Wanghuai Xu, Qianqian Miao, Zuankai Wang, Jian Zhang, Xiaofeng Zhou (2020)
Boosting the output performance of volume effect electricity generator (VEEG) with water columnNano Energy, 73
Yuan Kang, Yun Xia, Huanting Wang, Xiwang Zhang (2019)
2D Laminar Membranes for Selective Water and Ion TransportAdvanced Functional Materials, 29
Wanghuai Xu, Zuankai Wang (2020)
Fusion of Slippery Interfaces and Transistor-Inspired Architecture for Water Kinetic Energy HarvestingJoule, 4
Jiaqing Xiong, Meng-Fang Lin, Jiangxin Wang, Sheng Gaw, K. Parida, Pooi Lee (2017)
Wearable All‐Fabric‐Based Triboelectric Generator for Water Energy HarvestingAdvanced Energy Materials, 7
Yong Qin, Xudong Wang, Zhong Wang (2008)
Microfibre–nanowire hybrid structure for energy scavengingNature, 451
Chenxing Fan, Chuan Wu, Guojun Wen, Aiyan Wang, Qing Zhou (2020)
Development of self-powered bubble velocity sensor for gas–liquid two-phase flow based on triboelectric nanogeneratorNanotechnology, 32
Joule 2020 , 4 , 2527
Young-Man Choi, Moon-Gu Lee, Y. Jeon (2017)
Wearable Biomechanical Energy Harvesting TechnologiesEnergies, 10
Yuankai Jin, Chenyang Wu, Pengcheng Sun, Mingmei Wang, Miaomiao Cui, Chao Zhang, Zuankai Wang (2022)
Electrification of water: From basics to applicationsDroplet
Jian Yu, Enze Ma, T. Ma (2018)
Exponential energy harvesting through repetitive reconfigurations of a system of capacitorsCommunications Physics, 1
Seung‐Bae Jeon, Daewon Kim, Gun-Wook Yoon, Jun‐Bo Yoon, Yang-Kyu Choi (2015)
Self-cleaning hybrid energy harvester to generate power from raindrop and sunlightNano Energy, 12
Huawei Liu, Dong Li, Chao Ma, Xuehong Zhang, Xingxia Sun, Chenguang Zhu, B. Zheng, Zixing Zou, Ziyu Luo, Xiaoli Zhu, Xiao Wang, A. Pan (2019)
Van der Waals epitaxial growth of vertically stacked Sb2Te3/MoS2 p–n heterojunctions for high performance optoelectronicsNano Energy
Hao Wu, Zuankai Wang, Yunlong Zi (2021)
Multi‐Mode Water‐Tube‐Based Triboelectric Nanogenerator Designed for Low‐Frequency Energy Harvesting with Ultrahigh Volumetric Charge DensityAdvanced Energy Materials, 11
Peng Bai, G. Zhu, Zong‐Hong Lin, Qingshen Jing, Jun Chen, Gong Zhang, Jusheng Ma, Zhong Wang (2013)
Integrated multilayered triboelectric nanogenerator for harvesting biomechanical energy from human motions.ACS nano, 7 4
Song Jin, Yu Jiang, Hengxing Ji, Yan Yu (2018)
Advanced 3D Current Collectors for Lithium‐Based BatteriesAdvanced Materials, 30
Wanghuai Xu, Xiaofeng Zhou, Chonglei Hao, Huanxi Zheng, Yuan Liu, Xiantong Yan, Zhengbao Yang, M. Leung, X. Zeng, Ronald Xu, Zuankai Wang (2019)
SLIPS-TENG: robust triboelectric nanogenerator with optical and charge transparency using a slippery interfaceNational Science Review, 6
Zong‐Hong Lin, G. Cheng, Sangmin Lee, K. Pradel, Zhong Wang (2014)
Harvesting Water Drop Energy by a Sequential Contact‐Electrification and Electrostatic‐Induction ProcessAdvanced Materials, 26
Han Yan, Zexin Feng, Peixin Qin, Xiaorong Zhou, Huixin Guo, Xiaoning Wang, Hongyu Chen, Xin Zhang, Haojiang Wu, Chengbao Jiang, Zhiqi Liu (2020)
Electric‐Field‐Controlled Antiferromagnetic Spintronic DevicesAdvanced Materials, 32
Wei Tang, Tao Jiang, F. Fan, A. Yu, Chi Zhang, Xia Cao, Zhong Wang (2015)
Liquid‐Metal Electrode for High‐Performance Triboelectric Nanogenerator at an Instantaneous Energy Conversion Efficiency of 70.6%Advanced Functional Materials, 25
Harnessing ambient renewable mechanical energies for achieving carbon‐neutrality demands the rational design of materials and architectures which are favorable for both energy collection and conversion simultaneously. However, the direct coupling of energy collection and conversion modules leads to many unwanted problems such as material wearing, the spatial constraint for large‐scale integration, and low energy conversion efficiency. Herein, a remote‐controlled energy harvesting strategy that cleverly harnesses the unique advantage of diffusive, long‐range airflow within a confined capillary channel is developed. The reported device separates the energy collection unit, made of an elastic cavity that directly transforms external mechanical motion to pneumatic motion, from the conversion units, made of encapsulated droplet chains that serve to translate their recurring motion within the capillary channel into electrical output. In contrast to single‐drain electrode design for electricity generation from fresh droplets in open spaces, two drain electrodes are designed to collect and release electrostatically induced charges from recurring droplets in the confined channel, respectively, thereby eliminating unwanted charge accumulation on recurring droplets and leading to efficient output performance. The integration of multiple electricity generation units with such a two‐drain electrode architecture with a single energy collector improves the design resilience and relaxes the spatial limitation.
Advanced Energy Materials – Wiley
Published: Mar 1, 2023
Keywords: energy harvesting; electricity generators; integration; two‐drain electrode architecture; remote control
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.