杨希娅
副教授 硕士生导师
主要研究方向:纳米发电机及自驱动微系统
邮箱:xiyayang@jnu.edu.cn
地址:番禺校区李国华楼2012
杨希娅,副教授,硕士生导师,暨南杰青。2012年毕业于山东科技大学电气与自动化工程学院,获学士学位,授予山东省优秀毕业生称号。2017年于香港城市大学获得博士学位,随后继续在香港城市大学从事博士后研究。2018年9月至今加入暨南大学新能源技术研究院,任副教授。
主要研究领域为自驱动微纳机电系统,基于摩擦电、压电、电磁和光电等多效应耦合的多能(波浪能、雨能、人体动能、太阳能)采集自驱动微纳器件研发,在关键材料可控制备、器件结构优化设计和电源管理电路设计等方面开展了系列研究工作。迄今在能源材料领域国际刊物发表SCI论文累计50余篇,其中以第一/通讯(含共同)作者发表26篇,包括Energy & Environmental Science、Advanced Functional Materials、Advanced Science、ACS Nano、Nano Energy等,主持国家自然科学青年基金、省部级自然科学基金等项目,并作为核心成员参与国家重点研发计划1项,授权中国发明专利3项,外观设计专利1项。受邀担任Frontiers in Electronics: Wearable Electronics副主编、Nanomaterials - “Advances in Flexible Nanoelectronics”客座编辑、《材料研究与应用》青年编委,多次担任Advanced Materials、Advanced Energy Materials、Advanced Functional Materials、Nano Energy等国际学术期刊独立审稿人。
代表性论文:
1. H. Hong, ‡ X. Yang, ‡ * H. Cui, D. Zheng,H. Wen,R. Huang,L. Liu, J. Duan,Q. Tang*, Self-powered seesaw structured spherical buoys based on hybrid triboelectric-electromagnetic nanogenerator for sea surface wireless positioning, Energy & Environmental Science, 2022, 15, 621-632.
2. Q. Guo, X. Yang*, Y. Wang, W. Xu, J. Duan, Q. Tang*, Dielectric hole collector towards boosting charges transfer of CsPbBr3 hybrid nanogenerator by coupling of triboelectric and photovoltaic effects, Advanced Functional Materials, 2021, 31, 32, 2101348.
3. L. Liu, X. Yang*, L. Zhao, H. Hong, H. Cui, J. Duan, Q. Yang, Q. Tang*, Nodding Duck Structure Multi-track Directional Freestanding Triboelectric Nanogenerator toward Low-Frequency Ocean Wave Energy Harvesting, ACS Nano, 2021, 15, 6, 9412–9421.
4. X. Yang,* G. Liu, Q. Guo, H. Wen, R. Huang, X. Meng, J. Duan, Q. Tang*, Triboelectric Sensor Array for Internet of Things based Smart Traffic Monitoring and Management System, Nano Energy, 2022, 92, 106757.
5. H. Wen, X. Yang*, R. Huang, D. Zheng, J. Yuan, H. Hong, J. Duan, Y. Zi, Q. Tang*, Universal Energy Solution for Triboelectric Sensors Toward the 5G Era and Internet of Things, Advanced Science, 2023, 10, 22, 2302009.
6. X. Yang, W. A. Daoud*, Triboelectric and Piezoelectric Effects in a Combined Tribo-Piezoelectric Nanogenerator Based on an Interfacial ZnO Nanostructure, Advanced Functional Materials,2016, 26, 8194–8201.
7. L. Zhao,J. Duan,* L. Liu, J. Wang, Y. Duan, L. V. Roca, X. Yang,* Q. Tang*, Boosting Power Conversion Efficiency by Hybrid Triboelectric Nanogenerator/Silicon Tandem Solar Cell toward Rain Energy Harvesting, Nano Energy, 2021, 82, 105773
8. L. Liu, J. Li,* Z. Guan, L. Zhao, Z. Tian, S. Jia, H. Hong, Z. He, H. Wen, R. Huang, H. Cui, W. Ou-Yang,* X. Yang,* Ultra-high output hybrid nanogenerator for self-powered smart mariculture monitoring and warning system, Chemical Engineering Journal, 2023, 472, 145039.
9. X. Yang, S. Chan, L. Wang, W. A. Daoud*, Water tank triboelectric nanogenerator for efficient harvesting of water wave energy over a broad frequency range, Nano Energy,2018, 44, 388-398.
10.X. Yang, W. A. Daoud*, Design parameters impact on output characteristics of flexible hybrid energy harvesting generator: Experimental and theoretical simulation based on a parallel hybrid model,Nano Energy, 2018, 50, 794-806.