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孙志军

孙志军的头像

个人信息

职称
教授
Email
sunzj@xmu.edu.cn
工作电话
0592-2187109
办公室
物理馆427
个人主页
http://mnplab.xmu.edu.cn/
研究领域
  • 金属基纳米光学(Nano-Optics)及等离激元光学(Plasmonics)结构、材料与器件
  • 微纳光学结构与纳米材料的光相互作用
  • 新型光电子器件及其集成技术
个人简历
  • 2005年~今,     厦门大学物理系副教授、教授、博士生导师。
  • 2000~2005年, 美国匹兹堡大学电子工程系博士生(Ph.D.)
  • 1997~2000年, 兰州大学物理系微电子学硕士研究生(M.E.) 
  • 1993~1997年, 兰州大学物理系本科生(B.S.) 
 
代表性研究成果:
发表学术论文40余篇,其中被SCI收录38篇,SCI统计他引640多次(截止20142月)。获美国和中国发明专利7项。
(1)首先在实验上展示了厚亚波长周期性金属纳米缝隙结构的透射光谱,并对其中表面等离激元波效应的作用进行了研究,实现了相关结构的窄带透射 [APL 83, 3021 (2003); APL 86, 23111 (2005); J. Mod. Opt. 55, 1639 (2008);APL 101, 171106(2012)]。
(2)首先提出了基于金属纳米光学结构透镜的概念,设计研究了若干具有代表性的光束整形微光学器件结构 [APL 85, 642 (2004); APL 89, 261119 (2006)]。
(3)发展了一种异质衬底上制备阳极氧化铝微纳孔阵列结构的新技术 [APL 81, 3458 (2002)];
(4)利用超快双光子干涉技术首次直接观察到了表面等离激元电子密度波的振荡状态 [Nano Lett. 5, 1123 (2005)]。
(5)揭示了基于超薄金属膜微纳结构材料的异常光学效应,包括抑制透射、增强吸收和可调滤波 [Plasmonics 5, 13 (2010); Plasmonics 6, 83 (2011); Plasmonics 6, 745 (2011)]。
(6)理论上揭示了太阳能电池表面金属纳米颗粒并不能直接增强其中的光吸收,这个发现澄清了这个研究热点上人们广泛存在的一个误解[Opt. Lett. 37, 641 (2012)];
(7)低损耗等离激元光波导方面:提出了若干中表面等离激元光波导,尤其是一种具有低损耗的混合模等离激元光波导[APL 91, 111112 (2007); JOSAB 24, 2883 (2007); OL 36, 2946 (2011)]。
(8)提出了在金属表面实现TE准表面波的方法,展示了其在TE偏振光在金属微纳结构中的异常介观光学效应的作用和表现特性[OE 22,4714 (2014); OL 39, 2637 (2011);APE 7, 32001 (2014)]。
在研基金
  • 国家自然科学基金面上项目:一种低损耗混合模等离激元光波导的模式、耦合特性及其集成问题的研究(2013-2016,主持)
  • 福建省自然科学基金杰青项目:低损耗等离激元光波导的研究 (2011-2014,主持)
  • 国家重大科学研究计划项目子课题:硅基混合集成微纳结构高速高灵敏度光电探测器的研究(2012-2016,参加)
  • 教育部新世纪优秀人才支持计划:金属微纳结构中的光学效应及其等离激子器件的研究(20092011,主持)
  • 教育部高等学校博士点基金: 低损耗金属/介质复合纳米材料等离激子波导器件的研究 (2008-2010,主持)
  • 国家自然科学基金: 低损耗金属/介质复合纳米材料等离激子波导集成光路研究 (2008-2010,主持)
  • 福建省科技计划重点项目: 防辐射、防紫外、高导电率透明金属/介质复合薄膜的研制 (2007-2009,主持)
  • 福建省自然科学基金: 纳米压印技术在等离激子波集成光学器件上的应用研究 (2007-2009,主持)
发表文章
以第一或(和)通迅作者发表的代表性论文:
  1. Aihua Li, Tengpeng Guan and Zhijun Sun*, “Opposite size-dependences of the red/green upconversion intensity ratio in sub-20 nm Yb3+,Er3+-doped b-NaGdF4 nanophosphors,” Europhysics Letters, Vol. 106, 48001 (2014).
  2. Zhijun Sun*, Wei Chen, and Ling Guo, “Nearly perfect resonant absorption of TE–polarized light at metal surfaces coated with arrayed dielectric stripes,” Optics Letters, Vol. 39, No. 9, 2637-2640 (2014) .
  3. Zhijun Sun*, Xiaoliu Zuo, Tengpeng Guan, and Wei Chen, “Artificial TE-mode surface waves at metal surfaces mimicking surface plasmons,” Optics Express, Vol. 22, No. 4, 4714-4722 (Feb., 2014).
  4. Xiaoliu Zuo and Zhijun Sun*, “Hybrid surface plasmon modes in metal-clad Si/SiO2 waveguide for compact integration,” Frontiers of Optoelectronics, Vol. 6, No. 3, 261-269 (2013).
  5. Zhijun Sun*, Ying Yang, and Xiaoliu Zuo, “Narrow-band optical transmission of metallic nanoslit arrays,” Applied Physics Letters, Vol. 101, Iss. 17, 171106-1-4 (2012).
  6. Zhijun Sun*, Xiaoliu Zuo, and Ying Yang, “Role of surface metal nanoparticles on the absorption in solar cells,” Optics Letters, Vol. 37, No. 4, 641-643 (2012).
  7. Jie Li, Qi Lin and Zhijun Sun*, “Photoluminescence of Er silicates on microstructured Si substrate,” Journal of Luminescence, Vol. 132, Iss. 2, 325-329 (2012) .
  8. Zhijun Sun*, Xiaoliu Zuo, and Jie Li, “Optical transmission through multilayered ultra-thin metal gratings,” Plasmonics, Vol. 6, Iss. 4, 745-751 (2011).
  9. Xiaoliu Zuo and Zhijun Sun*, “Low-loss plasmonic hybrid optical ridge waveguide on silicon-on-insulator substrate,” Optics Letters, Vol. 36, No. 15, 2946-2948 (2011).
  10. Zhijun Sun* and Xiaoliu Zuo, “Tunable absorption of light via localized plasmon resonances on a metal surface with interspaced ultra-thin metal gratings,” Plasmonics, Vol. 6, Iss. 1, 83-89 (2011).
  11. Qi Lin and Zhijun Sun*, “Optical extinction properties of aggregated ultra-fine silver nanoparticles on silica nanospheres,” The Journal of Physical Chemistry C, Vol. 115, Iss. 5, 1474-1479 (2011).
  12. Zhijun Sun*, Xiaoliu Zuo and Qi Lin, “Plasmon-induced nearly null transmission of light through gratings in very thin metal films,” Plasmonics, Vol. 5, Iss. 1, 13-17 (2010).
  13. Zhijun Sun* and Xiaoliu Zuo, “Tuning resonant optical transmission of metallic nanoslit arrays with embedded microcavities”, Optics Letters, Vol. 34, Iss. 9, 1411-1413 (2009).
  14. Zhijun Sun*, Qi Lin, and Wei Chen “Low-loss, compact waveguiding with TE mode in metal/dielectric waveguides for planar light wave circuit”, Optics Communications, Vol. 282, No. 10, 2036-2039 (2009).
  15. Zhijun Sun* and Qi Lin, “Study of a Fabry-Perot-like microcavity with sandwiched metallic gratingsfor tunable filter arrays”, IEEE Photonics Technology Letters, 20(13), 1157-1159 (2008).
  16. Zhijun Sun* and Danyan Zeng, “Modeling optical transmission spectra of periodic narrow slit arrays in thick metal films and their correlation with those of individual slits”, Journal of Modern Optics, 55(10), 1639-1647 (2008).
  17. Zhijun Sun*, “Vertical dielectric-sandwiched thin metal layer for compact, low-loss long range surface plasmon waveguiding”, Applied Physics Letters, 91(11), 111112 (2007).
  18. Zhijun Sun* and Danyan Zeng, “Coupling of surface plasmon waves in metal/dielectric gap waveguides and single interface waveguides”, Journal of the Optical Society of America B, 24(11), 2883-2887 (2007).
  19. Zhijun Sun*, “Beam splitting with a modified metallic nano-optic lens”, Applied Physics Letters, 89(26), 261119 (2006).
  20. Zhijun Sun and Hong Koo Kim*, “Refractive transmission of light and beam shaping with metallic nano-optic lenses”, Applied Physics Letters, 85(4), 0642 (2004). Cover Image
  21. Zhijun Sun, Yun Suk Jung and Hong Koo Kim*, “Role of surface plasmons in the optical interaction in metallic gratings with narrow slits”, Applied Physics Letters, 83(15), 3021 (2003).
  22. Zhijun Sun and Hong Koo Kim*, “Growth of ordered, single-domain, alumina nanopore arrays with holographically patterned aluminum films”, Applied Physics Letters81 (18), 3458 (2002).
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