陈杰
近期热点
资料介绍
个人简历
教育背景 2007 - 2011,新加坡国立大学,物理学,博士 2005 - 2007,南京大学,声学,硕士 2001 - 2005,南京大学,声学,学士 工作经历 2018 - 至今, 同济大学,物理科学与工程学院,教授 2015 - 2017,同济大学,物理科学与工程学院,“领航计划”特聘研究员 2013 - 2015,瑞士苏黎世联邦理工学院,机械系,ETH Fellow 2011 - 2013,新加坡国立大学,物理系,博士后研究领域
纳米尺度热传导的理论研究及数值模拟 二维材料的热输运性质 热电材料及散热材料 分子动力学模拟近期论文
20. S. Hu+, Z. Zhang+, P. Jiang, J. Chen*, S. Volz*, M. Nomura, and B. Li*, Randomness-Induced Phonon Localization in Graphene Heat Conduction, J. Phys. Chem. Lett. 9, 3959-3968 (2018). 19. Z. Zhang, S. Hu, T. Nakayama, J. Chen*, and B. Li, Reducing lattice thermal conductivity in schwarzites via engineering the hybridized phonon modes, Carbon 139, 289-298 (2018). 18. Y. Ma+, Z. Zhang+, J.-G. Chen, K. Saaskilahti, S. Volz, and J. Chen*, Ordered water layer induced by interfacial charge decoration leads to an ultra-low Kapitza resistance between graphene and water, Carbon 135, 263-269 (2018). 17. X. Xu, J. Chen*, J. Zhou*, and B. Li, Thermal Conductivity of Polymers and Their Nanocomposites, Adv. Mater. 30, 1705544 (2018). 16. Z. Zhang, J. Chen*, and B. Li*, Negative Gaussian curvature induces significant suppression of thermal conduction in carbon crystals, Nanoscale 9, 14208-14214 (2017). 15. H. Wang+, S. Hu+, K. Takahashi, X. Zhang*, H. Takamatsu*, and J. Chen*, Experimental study of thermal rectification in suspended monolayer graphene, Nat. Commun. 8, 15843 (2017). 14. Z. Zhang, S. Hu, J. Chen*, and B. Li*, Hexagonal boron nitride: a promising substrate for graphene with high heat dissipation. Nanotechnology 28, 225704 (2017). 13. S. Hu, J. Chen*, N. Yang, and B. Li*, Thermal transport in graphene with defect and doping: Phonon modes analysis. Carbon 116, 139-144 (2017). 12. 张忠卫,陈杰*,二维材料中的热传导,中国材料进展,第36卷,第2期,141-148 (2017). (特邀综述) 11. J. Chen*, J. H. Walther, and P. Koumoutsakos*, Ultrafast cooling by covalently bonded graphene-carbon nanotube hybrid immersed in water. Nanotechnology 27, 465705 (2016). 10. J. Chen*, J. H. Walther*, and P. Koumoutsakos*, Covalently bonded graphene-carbon nanotube hybrid for high-performance thermal interfaces. Adv. Funct. Mater. 25, 7539 (2015). 9. D. Alexeev+, J. Chen+, J. H. Walther, K. P. Giapis, P. Angelikopoulos, and P. Koumoutsakos*, Kapitza resistance between few-layer graphene and water: Liquid layering effects. Nano Lett. 15, 5744 (2015). 8. J. Chen, J. H. Walther, and P. Koumoutsakos*, Strain engineering of Kapitza resistance in few-layer graphene. Nano Lett. 14, 819 (2014). 7. J. Chen*, G. Zhang*, and B. Li*, Substrate coupling suppresses size dependence of thermal conductivity in supported graphene. Nanoscale 5, 532 (2013). 6. J. Chen, G. Zhang*, and B. Li, Impacts of atomistic coating on thermal conductivity of germanium nanowires. Nano Lett. 12, 2826 (2012). 5. J. Chen, G. Zhang*, and B. Li*, Phonon coherent resonance and its effect on thermal transport in core-shell nanowires. J. Chem. Phys. 135, 104508 (2011). 4. J. Chen, G. Zhang*, and B. Li, A universal gauge for thermal conductivity of silicon nanowires with different cross sectional geometries. J. Chem. Phys. 135, 204705 (2011). 3. J. Chen, G. Zhang*, and B. Li, Remarkable reduction of thermal conductivity in silicon nanotubes. Nano Lett. 10, 3978 (2010). 2. J. Chen, G. Zhang*, and B. Li, Tunable thermal conductivity of Si1-xGex nanowires. Appl. Phys. Lett. 95, 073117 (2009). 1. J. Chen, J. -C. Cheng, and B. Li*, Dynamics of elastic waves in two-dimensional phononic crystals with chaotic defect. Appl. Phys. Lett., 91, 121902 (2007). 相关热点
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