个人简介:个人简历:
2018.09-至今,南京邮电大学材料科学与工程学院,教授;
2015.08-2018.08,厦门大学能源学院,能效工程研究所副所长、助理教授、硕士生导师;
2012.08-2014.10,美国佐治亚理工学院材料科学与工程系,联合培养博士研究生
2012.02-2012.06,美国特拉华大学物理系,访问博士研究生
2007.09-2014.12,厦门大学物理系,微电子学与固体电子学,工学博士;
2003.09-2007.07,南京理工大学理学院,应用物理学,理学学士
研究方向:
(1)纳米发电机与微纳能源
(2)柔性电子与传感
(3)自驱动能源系统
(4)纳米功能材料与应用
(5)半导体光电器件
主要研究项目:
(1)国家自然科学基金面上项目,柔性摩擦电子学光热电器件研究,2020.01-2023.12,主 持
(2)国家自然科学基金青年基金项目,基于摩擦纳米发电机的柔性可穿戴自驱动紫外光电探测系统及其相关机理研究,2017.01-2019.12,主 持
(3)南京邮电大学引进人才科研启动基金,新型纳米发电机研制及其应用,2018.08-2021.07,主 持
(4)福建省自然科学基金面上项目,基于摩擦纳米发电机的柔性发电薄膜的研制及其在可穿戴器件中的应用研究,2016.04-2019.04,主 持,已结题
(5)福建省教育厅科技项目,表面功能化处理对摩擦纳米发电机电学性能的影响。2016.06-2018.05,主 持,已结题
主要学术成绩:
在摩擦纳米发电机的基本工作原理和实际应用、自驱动力学传感系统、高性能紫外光电探测器方面取得多项重要研究成果,被Reuters、CCTV、Chemical & EngineeringNews、Advances in Engineering等多家国内外媒体报道。在国际知名学术刊物Advanced Materials、ACS Nano、Nano Energy、Nature Communications、Nano Letters等上发表学术论文30 多篇,4篇入选ESI高被引论文,被引用3516次,H因子为23。申请13项专利、已授权中国发明专利7项、中国实用新型专利1项、美国发明专利1项,已授权8项。担任Advanced Functional Materials、Nano Energy、ACS Nano、Applied Physics Reviews、Nano-Micro Letters、Applied Energy、Chemical Engineering Journal、IEEE Transactions on IndustrialElectronics、Science Bulletin、Advanced MaterialsTechnologies等20多个国际期刊审稿人。
奖励荣誉:
(1) 厦门市“双百计划”高层次人才、领军型人才(2015)
(2) 福建省优秀博士学位论文(2015)
研究领域:
科研论文代表作:
(1)C. Y. Zhao, X. L. Wang, X. Chen, Y. Liu, Yannan Xie*(通讯作者), and H. Xu*, “Covalent interactions between carbonnanotube and P3HT by thiol-ene click chemistry towards improved thermoelectricperformance”, Materials Chemistry Frontiers, 4,1174-1181, (2020).
(2)YannanXie*(通讯作者), W. F. Yang, Q. H. Xu, X. Y. Shi, Y. Li,H. L. Huang, R. D. Hong, X. P. Chen, and Z. Y. Wu*, “Effects of Thermal Annealing on Ti/AuContacts to Anatase TiO2 Nanocrystal Films Prepared by Sol-Gel Method”, Journal of Nanoelectronics andOptoelectronics, 15, 389-393, (2020).
(3)H. B. Lin, Y. Liu, S. L. Chen, Q. H. Xu,S. T. Wang, T. Hu, P. F. Pan, Y. Z. Wang, Y. L. Zhang, N. Li, Y. Li, Y. W. Ma, Yannan Xie*(通讯作者), and L. H. Wang*, “Seesaw structured triboelectricnanogenerator with enhanced output performance and its applications inself-powered motion sensing”, Nano Energy, 65, 103944, (2019).
(4)H. B. Lin, M. H. He, Q. S. Jing, W. F.Yang, S. T. Wang, Y. Liu, Y. L. Zhang, J. Li, N. Li, Y. W. Ma, L. H. Wang*, andYannan Xie*(通讯作者), “Angle-Shaped Triboelectric Nanogeneratorfor Harvesting Environmental Wind Energy”, Nano Energy, 56, 269-276, (2019).
(5)Y. J. Yu, Y. C. Wang, S. Zhang, P. Y.Zhang, S. Xue, Yannan Xie*(通讯作者),Z. Y. Zhou*, J. Li*, and J. Y. Kang, “The construction of integrated Si-basedmicro proton exchange membrane fuel cells with improved performances”, Nano Energy, 61, 604-610, (2019).
(6)M. H. He, Y. J. Lin, C. M. Chiu, W. F.Yang, B. B. Zhang, D. Q. Yun, YannanXie*(通讯作者), and Z. H. Lin*, “A Flexible Photo-ThermoelectricNanogenerator Based on MoS 2/PU Photothermal Layer for Infrared LightHarvesting”, Nano Energy, 49, 588-595, (2018).
(7)S. T. Wang, M. H. He, B. J. Weng, L. H.Gan, Y. R. Zhao, N. Li, Yannan Xie*(通讯作者), “Stretchable and Wearable TriboelectricNanogenerator Based on Kinesio Tape for Self-Powered Human Motion Sensing”, Nanomaterials, 8, 657, (2018).
(
8)YannanXie, T. M. Chou, W. F. Yang,M.H. He, Y. R. Zhao, N. Li, and Z. H. Lin*, “Flexible thermoelectric nanogeneratorbased on the MoS2/graphene nanocomposite and its application for a self-poweredtemperature sensor”, Semiconductor Science and Technology,32, 044003, (2017).
(9)L. Lin+, Yannan Xie+(共同第一作者), S. M. Niu, S. H. Wang, P. K. Yang, andZ. L. Wang*, “Robust triboelectric nanogenerator based on rollingelectrification and electrostatic induction at an instantaneous energyconversion efficiency of ~55%”, ACS Nano, 9, 922-930, (2015).
(10)YannanXie+, S. H. Wang+, S.M. Niu+, L. Lin, Q. S. Jing, J. Yang, Z. Y. Wu, and Z. L. Wang*, “Grating-structured freestandingtriboelectric-layer nanogenerator for harvesting mechanical energy at 85% totalconversion efficiency”, Advanced Materials, 26, 6599-6607,(2014).
(11)YannanXie+, S. H. Wang+, S.M. Niu, L. Lin, Q. S. Jing, Y. J. Su, Z. Y. Wu, and Z. L. Wang*, “Multi-layered disk triboelectricnanogenerator for harvesting hydropower”, Nano Energy, 6, 129-136, (2014).
(12)S. H. Wang+, Yannan Xie+(共同第一作者), S. M. Niu+, L. Lin, and Z. L. Wang*, “Freestanding triboelectric-layer-basednanogenerators for harvesting energy from a moving object or human motion incontact and non-contact modes”, Advanced Materials, 26, 2818-2824,(2014). (ESI高被引论文)
(13)YannanXie+, S. H. Wang+, L.Lin, Q. S. Jing, Z. H. Lin, S. M. Niu, Z. Y. Wu, and Z. L. Wang*, “Rotary triboelectric nanogenerator basedon a hybridized mechanism for harvesting wind energy”, ACS Nano, 7, 7119-7125, (2013).
(14)L. Lin+, Yannan Xie+(共同第一作者), S. H. Wang+, W. Z. Wu, S. M. Niu, X. N.Wen, and Z. L. Wang*, “Triboelectric active sensor array for self-poweredstatic and dynamic pressure detection and tactile imaging”, ACS Nano, 7, 8266-8274, (2013). (ESI高被引论文)
(15)YannanXie, H. L. Huang, W. F.Yang, and Z. Y. Wu*, “Low dark current metal-semiconductor-metal ultravioletphotodetectors based on sol-gel-derived TiO2 films”, Journal of Applied Physics, 109,023114, (2011).
(16)Q. S. Jing, Yannan Xie, G. Zhu, R. P. S. Han, and Z. L. Wang*, “Self-powered thin-film motion vectorsensor”, Nature Communications, 6, 8031,(2015).
(17)S. H. Wang, Yannan Xie, S. M. Niu, L. Lin, C. Liu, Y. S. Zhou, and Z. L. Wang*,“Maximum surfacecharge density for triboelectric nanogenerators achieved by ionized-airinjection: methodology and theoretical understanding”, Advanced Materials, 26, 6720-6728,(2014).
(18)Z. H. Lin, Yannan Xie, Y. Yang, S. H. Wang, G. Zhu, and Z. L. Wang*, “Enhanced triboelectric nanogenerators andtriboelectric nanosensor using chemically modified TiO2 nanomaterials”, ACS Nano, 7, 4554–4560, (2013).
(19)S. H. Wang, L. Lin, Yannan Xie, Q. S. Jing, S. M. Niu, and Z. L. Wang*, “Sliding-triboelectric nanogenerators basedon in-plane charge-separation mechanism”, Nano Letters, 13, 2226-2233, (2013).(ESI高被引论文)
(20)L. Lin, S. H. Wang, Yannan Xie, Q. S. Jing, S. M. Niu, Y. F. Hu, and Z. L. Wang*, “Segmentally structured disk triboelectricnanogenerator for harvesting rotational mechanical energy”, Nano Letters, 13, 2916-2923, (2013).(ESI高被引论文)
