李继玲 - 中山大学 - 材料科学与工程学院

个人简介

学历与工作经历 1999.09-2003.07 山东大学物理学院学士学位 2003.08-2008.06 山东大学物理学院硕博连读 2008.07-2015.12 中山大学物理科学与工程技术学院师资博士后&讲师 2016.01-至今中山大学材料科学与工程学院副教授

研究领域

1. 纳米材料合成过程中杂质、缺陷效应及相关物理的理论研究； 2. 新型纳结构的特性表征及理论验证，功能结构组装和宏观性能调控； 3. 纳米材料和纳米结构的新能源应用； 4. 低维纳米材料物理与纳米电子器件及应用； 5. 纳米结构中的界面结构和界面效应欢迎有兴趣的本科生、研究生进组参加研究工作.

近期论文

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1. Carbyne with finite length: the one-dimensional sp-carbon B. T. Pan†, J. Xiao†, J. L, Li†,(共同第一) P. Liu, C. X. Wang, G. W. Yang * Science advances 1 (2015) e1500857 2. Ultrahigh-capacity Molecular Hydrogen Storage of Lithium-decorated Boron Monolayer J. L. Li, H.Y. Zhang and G. W. Yang The Journal of Physical Chemistry C 119,19681（2015） 3. Electronic Reconstruction of R‑Ag2WO4 Nanorods for Visible-Light Photocatalysis Z.Y. Lin,† J.L. Li† (共同第一)Z.Q. Zheng, J.H. Yan, P. Liu, C. X. Wang, and G. W Yang* ACS nano9,7256(2015). 4. An all-purpose building block: B12N12 fullerene J. L. Li, T. He and G. W. Yang Nanoscale 4, 5 （2012） (一区) 5. A new phase transformation path from nanodiamond to new-diamond via an intermediate carbon onion J. Xiao, J. L. Li(共同第一)，P. Liu and G. W. Yang Nanoscale 6，15098（2014） (一区) 6. Ferromagnetism and semiconducting of boron nanowires J. L. Li, T. He and G. W. Yang Nanoscale Research Letters 7, 678（2012） 7. Ni@B80: A single molecular magnetic switch J. L. Li and G. W. Yang Applied Physics Letters 95,133115 (2009). 8. Iron Endohedral-Doped Boron Fullerene: A Potential Single Molecular Device with Tunable Electronic and Magnetic Properties J. L. Li and G. W. Yang Journal of Physical Chemistry C 113,18292 (2009). 9. Tuning electronic and magnetic properties of endohedral Co@B80 and exohedral Co-B80 metallofullerenes by positioning Co atom J. L. Li and G. W. Yang Journal of Applied Physics 107,113702 (2010). 10. Ni endohedral-doped C60 with duality of magnetic moments J. L. Li and G. W. Yang Applied Physics Letters 96, 233103（2010） 11. High-capacity hydrogen storage of magnesium-decorated boron fullerene J. L. Li, Z.S.Hu, G.W. Yang Chemical Physics 392, 16-20（2010） 12. Tuning bandgap of Si-C heterofullerene-based nanotubes by H adsorption LI Ji-Ling, YANG Guo-Wei, ZHAO Ming-Wen, LIU Xiang-Dong,and Xia Yue-Yuan Chinese Physics Letters 27, 097101（2010） 13.Physical Origin of General Oscillation of Structure, Surface Energy, and Electronic Property in Rutile TiO2 Nanoslab T. He, J. L. Li and G. W. Yang ACS Applied Materials & Interfaces 4, 4 2192-2198 (2012) 14. Band-engineered CaTiO3 nanowires for visible light photocatalysis Q. Fu, J. L. Li, T. He and G. W. Yang Journal of Applied Physics 113, 10 (2013 ) 15. Electrical field induced direct-to-indirect bandgap transition in ZnO nanowires S. Li, J. L. Li, Q. Jiang, and G. W. Yang Journal of Applied Physics 108,024302 (2010). 16. Band-engineered SrTiO3 nanowires for visible light photocatalysis Q. Fu, T. He, J. L. Li, and G. W. Yang Journal of Applied Physics 112, 10 (2012) 17. Surface effect on electronic and optical properties of Bi2Ti2O7 nanowires for visible light photocatalysis Q. Fu, T. He, J. L. Li, and G. W. Yang Journal of Applied Physics 111, 12 (2012) 18. Surface Effect and Band-Gap Oscillation of TiO(2) Nanowires and Nanotubes T. He, Z. S. Hu, J. L. Li, G. W. yang The Journal of Physical Chemistry C 115,13837 (2011)