Yunlong Zi, Ph.D.
Affiliations: | 2005-2009 | Materials Science and Engineering | Tsinghua University, Beijing, China, Beijing, Beijing Shi, China |
2009-2014 | Physics and Astronomy | Purdue University, West Lafayette, IN, United States | |
2014-2017 | Materials Science and Engineering | Georgia Institute of Technology, Atlanta, GA | |
2017- | Mechanical and Automation Engineering | The Chinese University of Hong Kong, Hong Kong, Hong Kong |
Area:
Energy harvesting, nanogenerator, triboelectricWebsite:
https://zilab.weebly.com/Google:
"Yunlong Zi"Cross-listing: Chemistry Tree - Physics Tree
Parents
Sign in to add mentorChen Yang | grad student | 2014 | Purdue (Chemistry Tree) | |
(Control and understanding growth of III-V nanowires structures.) | ||||
Zhong Lin Wang | post-doc | 2014-2017 | Georgia Tech (Chemistry Tree) |
Children
Sign in to add traineeJingjing Fu | grad student | 2018- | Chinese University of Hong Kong (Chemistry Tree) |
Xin Xia | grad student | 2018- | Chinese University of Hong Kong (Chemistry Tree) |
Guoqiang Xu | grad student | 2018- | Chinese University of Hong Kong (Chemistry Tree) |
Haoyu Wang | grad student | 2019- | Chinese University of Hong Kong (Chemistry Tree) |
Dong Guan | post-doc | 2019- | Chinese University of Hong Kong (Chemistry Tree) |
Jiaqi Wang | post-doc | 2019- | Chinese University of Hong Kong (Chemistry Tree) |
Lingyun Wang | post-doc | 2019- | Chinese University of Hong Kong (Chemistry Tree) |
Xiaoyi Li | post-doc | 2018-2019 | Chinese University of Hong Kong (Chemistry Tree) |
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Publications
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Dai J, Xia X, Zhang D, et al. (2024) High-performance self-desalination powered by triboelectric-electromagnetic hybrid nanogenerator. Water Research. 252: 121185 |
Chen C, Zhang H, Xu G, et al. (2023) Passive Internet of Events Enabled by Broadly Compatible Self-Powered Visualized Platform Toward Real-Time Surveillance. Advanced Science (Weinheim, Baden-Wurttemberg, Germany). e2304352 |
He J, Guo X, Pan C, et al. (2023) High output soft-contact fiber-structure triboelectric nanogenerator and its sterilization application. Nanotechnology |
Wen H, Yang X, Huang R, et al. (2023) Universal Energy Solution for Triboelectric Sensors Toward the 5G Era and Internet of Things. Advanced Science (Weinheim, Baden-Wurttemberg, Germany). e2302009 |
Choi D, Lee Y, Lin ZH, et al. (2023) Recent Advances in Triboelectric Nanogenerators: From Technological Progress to Commercial Applications. Acs Nano |
Xia X, Zhou Z, Shang Y, et al. (2023) Metallic glass-based triboelectric nanogenerators. Nature Communications. 14: 1023 |
Xu G, Fu J, Li C, et al. (2022) Understanding the Time-Lag Behavior of the Breakdown-Discharge Voltage. Acs Applied Materials & Interfaces |
Su L, Xiong Q, Wang H, et al. (2022) Porous-Structure-Promoted Tribo-Induced High-Performance Self-Powered Tactile Sensor toward Remote Human-Machine Interaction. Advanced Science (Weinheim, Baden-Wurttemberg, Germany). e2203510 |
Chen C, Zhao S, Pan C, et al. (2022) A method for quantitatively separating the piezoelectric component from the as-received "Piezoelectric" signal. Nature Communications. 13: 1391 |
Xu G, Guan D, Fu J, et al. (2022) Density of Surface States: Another Key Contributing Factor in Triboelectric Charge Generation. Acs Applied Materials & Interfaces |