考博考生生准备要参加博士研究生考试时,必须要先确定准备攻读博士的相关专业,然后选择该专业有招生需求的学校,接下来应该联系博士生导师,只有当博士生导师同意考生报考,考博生才可以报考。所以提前了解博士生导师的学术文章及联系方式很重要,新东方在线特整理了各招收博士院校博导的简介及联系方式供考博生参考。
王佳平
副研究员
清华大学物理系
纳米中心
北京 100084
电话:010-62796007
传真:010-62792457
jpwang@tsinghua.edu.cn
个人网页:
个人简历
教育
英国剑桥大学 材料科学系 博士学位 (2002)
清华大学 材料科学与工程系 学士学位 (1996)
工作经历
清华大学 物理系 副研究员 (2007-)
美国路易斯安那州立大学 机械工程系 助理教授(2005-2007)
美国约翰霍普金斯大学 材料科学与工程系 博士后 (2002-2005)
教学
研究领域
1.锂离子电池
2.超级电容器
3.碳纳米管复合材料
本研究小组现招收博士后和研究生,也欢迎本科生参加科研项目。
请Email联系jpwang@tsinghua.edu.cn。
奖励、荣誉和学术兼职
主要论著
1. L. Sun, W. B. Kong, Y. Jiang, H. C. Wu, K. L. Jiang, J. P. Wang, and S. S. Fan, “Super-aligned carbon nanotube/graphene hybrid materials as framework for sulfur cathodes in high performance lithium sulfur batteries”, J. Mater. Chem. A, in press, (2014).
2. L. Sun, M. Y. Li, Y. Jiang, W. B. Kong, K. L. Jiang, J. P. Wang, and S. S. Fan, “Sulfur nanocrystals confined in carbon nanotube network as a binder-free electrode for high-performance lithium sulfur batteries”, Nano Lett., 14, 4044–4049, (2014).
3. M. Y. Li, Y. Wu, F. Zhao, Y. Wei, J. P. Wang, K. L. Jiang, and S. S. Fan, “Cycle and rate performance of chemically modified super-aligned carbon nanotube electrodes for lithium ion batteries”, Carbon, 69, 444-451, (2014).
4. S. Luo, H. C. Wu, Y. Wu, K. L. Jiang, J. P. Wang, and S. S. Fan, “Mn3O4 nanoparticles anchored on continuous carbon nanotube network as superior anodes for lithium ion batteries”, J. Power Sources, 249, 463–469, (2014).
5. L. Sun, J. P. Wang, K. L. Jiang, and S. S. Fan, “Mesoporous Li4Ti5O12 nanoclusters as high performance negative electrodes for lithium ion batteries”, J. Power Sources, 248, 265-272, (2014).
6. Y. Wu, H. C. Wu, S. Luo, K. Wang, F. Zhao, Y. Wei, P. Liu, K. L. Jiang, J. P. Wang, and S. S. Fan, “Entrapping electrode materials within ultrathin carbon nanotube network for flexible thin film lithium ion batteries”, RSC Advances, 4, 20010-20016, (2014).
7. Y. Wu, J. P. Wang, K. L. Jiang, and S. S. Fan, “The applications of carbon nanotubes in high performance lithium ion batteries”, Frontiers of Physics, 9, 351-369, (2014).
8. H. Zheng, D. D. Xiao, X. Li, Y. L. Liu, Y. Wu, J. P. Wang, K. L. Jiang, C. Chen, L. Gu, X. L. Wei, Y. S. Hu, Q. Chen, H. Li, “New insight in understanding oxygen reduction and evolution in solid-state lithium oxygen batteries using an in situ environmental scanning electron microscope”, Nano Lett., 14, 4245-4249, (2014).
9. J. T. Wang, T. Y. Li, B. Y. Xia, X. Jin, H. M. Wei, W. Y. Wu, Y. Wei, J. P. Wang, P. Liu, L. N. Zhang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Vapor-condensation-assisted optical microscopy for ultralong carbon nanotubes and other nanostructures”, Nano Lett., 14, 3527-3533, (2014).
10. L. F. Fei, L. Sun, W. Lu, M. Guo, H. T. Huang, J. P. Wang, H. L. W. Chan, S. S. Fan, Y. Wang, “Stable 4 V-class bicontinuous cathodes by hierarchically porous carbon coating on Li3V2(PO4)3 nanospheres”, Nanoscale, 6, 12426-12433, (2014).
11. F. Zhu, X. Y. Lin, P. Liu, K. L. Jiang, Y. Wei, Y. Wu, J. P. Wang, S. S. Fan, “Heating graphene to incandescence and the measurement of its work function by the thermionic emission method”, Nano Research, 7, 553-560, (2014).
12. Y. J. He, D. Q. Li, T. Y. Li, X. Y. Lin, J. Zhang, Y. Wei, P. Liu, L. N. Zhang, J. P. Wang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Metal-film-assisted ultra-clean transfer of single-walled carbon nanotubes”, Nano Research, 7, 981-989, (2014).
13. Y. Wu, Y. Wei, J. P. Wang, K. L. Jiang, and S. S. Fan, “Conformal Fe3O4 sheath on aligned carbon nanotube scaffolds as high performance anodes for lithium ion batteries”, Nano Lett., 13, 818−823, (2013).
14. K. Wang, S. Luo, Y. Wu, X. F. He, F. Zhao, J. P. Wang, K. L. Jiang, and S. S. Fan, “Super-aligned carbon nanotube films as current collectors for lightweight and flexible lithium ion batteries”, Adv. Funct. Mater., 23, 846–853, (2013).
15. X. F. He, Y. Wu, F. Zhao, J. P. Wang, K. L. Jiang, and S. S. Fan, “Enhanced rate capabilities of Co3O4/carbon nanotube anodes for lithium ion battery applications”, J. Mater. Chem. A, 1, 11121 – 11125, (2013).
16. K. Wang, Y. Wu, S. Luo, X. F. He, J. P. Wang, K. L. Jiang, and S. S. Fan, “Hybrid super-aligned carbon nanotube/carbon black conductive networks: a strategy to improve both electrical conductivity and capacity for lithium ion batteries”, J. Power Sources, 233, 209-215, (2013).
17. X. Y. Lin, P. Liu, Y. Wei, Q. Q. Li, J. P. Wang, Y. Wu, C. Feng, L. N. Zhang, S. S. Fan, and K. L. Jiang, “Development of an ultra-thin film comprised of a graphene membrane and carbon nanotube vein support”, Nat. Commun., 4, 2920, (2013).
18. Y. J. He, J. Zhang, D. Q. Li, J. T. Wang, Q. Wu, Y. Wei, L. N. Zhang, J. P. Wang, P. Liu, Q. Q. Li, S. S. Fan, K. L. Jiang, “Evaluating Bandgap Distributions of Carbon Nanotubes via Scanning Electron Microscopy Imaging of the Schottky Barriers”, Nano Lett., 13, 5556–5562, (2013).
19. L. F. Fei, W. Lu, L. Sun, J. P. Wang, J. B. Wei, H. L. W. Chan, and Y. Wang, “Highly entangled carbon nanoflakes on Li3V2(PO4)3 microrods for improved lithium storage performance”, RSC Advances, 3, 1297–1301, (2013).
20. F. Hao, Z. Wang, Q. Luo, J. Lou, J. B. Li, J. P. Wang, S. S. Fan, K. L. Jiang, and H. Lin, “Highly catalytic cross-stacked superaligned carbon nanotube sheets for iodine-free dye-sensitized solar cells”, J. Mater. Chem., 22, 22756–22762, (2012).
21. J. Li, Y. J. He, Y. M. Han, K. Liu, J. P. Wang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Direct identification of metallic and semiconducting single-walled carbon nanotubes in scanning electron microscopy”, Nano Lett., 12, 4095–4101, (2012).
22. S. Luo, K. Wang, J. P. Wang, K. L. Jiang, Q. Q. Li, S. S. Fan, “Binder-free LiCoO2/carbon nanotube cathodes for high performance lithium ion batteries”, Adv. Mater., 24, 2294–2298, (2012).
23. R. Xie, J. P. Wang, Y. Yang, K. L. Jiang, Q. Q. Li, S. S. Fan, “Aligned carbon nanotube coating on polyethylene surface formed by microwave radiation”, Composites Science and Technology, 72, 85–90, (2011).
24. L. Z. Chen, C. H. Liu, K. Liu, C. Z. Meng, C. H. Hu, J. P. Wang, and S. S. Fan, “High-performance, low-voltage, and easy-operable bending actuator based on aligned carbon nanotube/polymer composites”, ACS Nano, 5 (3), 1588–1593, (2011).
25. K. L. Jiang, J. P. Wang, Q. Q. Li, L. Liu, C. H. Liu, and S. S. Fan, “Superaligned carbon nanotube arrays, films and yarns: a road to applications”, Adv. Mater., 23, 1154–1161, (2011).
26. K. Liu, Y. H. Sun, X. Y. Lin, R. F. Zhou, J. P. Wang, S. S. Fan, K. L. Jiang, “Scratch-resistant, highly conductive, and high-strength carbon nanotube-based composite yarns”. ACS Nano, 4, 5827–5834, (2010).
27. K. Liu, Y. H. Sun, R. F. Zhou, H. Y. Zhu, J. P. Wang, L. Liu, S. S. Fan and K. L. Jiang, “Carbon nanotube yarns with high tensile strength made by a twisting and shrinking method”, Nanotechnology, 21, Art. No. 045708, (2010).
28. Q. F. Cheng, J. P. Wang, J. J. Wen, C. H. Liu, K. L. Jiang, Q. Q. Li, and S. S. Fan, “Carbon nanotube/epoxy composites fabricated by resin transfer molding”, Carbon, 48, p. 260-266, (2010).
29. K. Liu, Y. H. Sun, P. Liu, J. P. Wang, Q. Q. Li, S. S. Fan, and K. L. Jiang, “Periodically striped films produced from super-aligned carbon nanotube arrays”, Nanotechnology, 20, Art. No. 335705, (2009).
30. L. Z. Chen, C. H. Liu, J. P. Wang, W. Zhang, C. H. Hu, and S. S. Fan, “Auxetic materials with large negative Poisson’s ratios based on highly oriented carbon nanotube structures”, Appl. Phys. Lett., 94, Art. No. 253111, (2009).
31. X. T. Qiu, R. R. Liu, S. M. Guo, J. H. Graeter, L. Kecskes, and J. P. Wang, “Combustion synthesis reactions in cold-rolled Ni/Al and Ti/Al multilayers”, Metall. Mater. Trans. A, 40A[7], p. 1541-1546, (2009).
32. Q. F. Cheng, J. P. Wang, K. L. Jiang, Q. Q. Li, and S. S. Fan, “Fabrication and properties of aligned multi-walled carbon nanotubes reinforced epoxy composites”, J. Mater. Res., 23[11], p. 2975-2983, (2008).
33. X. Qiu and J. Wang, “Bonding silicon wafers with reactive multilayer foils”, Sensors and Actuators A, 141[2], p. 476-481, (2008).
34. X. Qiu, J. H. Graeter, L. Kecskes, J. Wang, “Exothermic reactions in cold rolled Ni/Al reactive multilayer foils”, J. Mater. Res., 23(2), p. 367-375, (2008).
35. H. Nathani, J. Wang, and T. P. Weihs, “Long-term stability of nanostructured systems with negative heats of mixing”, J. Appl. Phys., 101[10], Art. No.104315, (2007).
36. X. Qiu and J. Wang, “Experimental evidence of two-stage formation of Al3Ni in reactive Ni/Al multilayer foils”, Scripta Mater., 56[12], p. 1055-1058, (2007).
37. J. C. Trenkle, J. Wang, T. P. Weihs, and T. C. Hufnagel, “Microstructural study of oscillatory combustion in nanostructured reactive multilayer foils”, Appl. Phys. Lett., 87[15], Art. No.153108, (2005).
38. J. Wang, E. Besnoin, O. M. Knio, and T. P. Weihs, “Effects of physical properties of components on reactive nanolayer joining”, J. Appl. Phys., 97 [11]: Art. No.114307, (2005).
39. J. Wang, E. Besnoin, O. M. Knio, and T. P. Weihs, “Investigating the effect of applied pressure on reactive multilayer foil joining”, Acta. Mater.,52[18],p.5265-5274, (2004).
40. A. Duckham, S. J. Spey, J. Wang, M. E. Reiss, T. P. Weihs, E. Besnoin, and O. M. Knio, “Reactive nanostructured foil used as a heat source for joining titanium”, J. Appl. Phys., 96[4], p.2336-2342, (2004).
41. J. Wang, E. Besnoin, A. Duckham, S. J. Spey, M. E. Reiss, O. M. Knio, and T. P. Weihs, “Joining of stainless steel specimens with nanostructured Al/Ni foils”, J. Appl. Phys., 95[1], p.248-256, (2004).
42. L. J. Vandeperre, J. Wang, and W. J. Clegg, “Effects of porosity on the measured fracture energy of brittle materials”, Phil. Mag., 84[34], p.3689-3704, (2004).
43. J. Wang, E. Besnoin, A. Duckham, S. J. Spey, M. E. Reiss, O. M. Knio, M. Powers, M. Whitener, and T. P. Weihs, “Room temperature soldering with nanostructured foils”, Appl. Phys. Lett., 83[19], p.3987-3989, (2003).
ResearcherID:K-7499-2012