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蔡国雄

发布时间:2017-06-09 浏览次数:55

姓名蔡国雄

职称、职位:助理教授

邮箱:gxcai8303ATxmu.edu.cn

电话:0592-2182531

办公地点:海韵园新大楼433


学历:

厦门大学工学学士,通信工程专业;

厦门大学理学硕士,无线电物理专业;

厦门大学工学博士,电路与系统专业。

研究方向:

计算光子学、纳米光子/光电子学

主讲课程:

电路分析原理

太赫兹与光电子技术(研究生课)

课题项目:

基于石墨烯等离激元的无标记生物传感器及其蛋白质分子检测研究,青年,2017/01-2019/12


代表作:

[1]Chen Y, Yao J, Song Z, Ye L, Cai G*, Liu QH, 2016. Independent tuning of double plasmonic waves in a free-standing graphene-spacer-grating-spacer-graphene hybrid slab. Optics Express 24(15): 16961-16972, doi: 10.1364/OE.24.016961 (SCI/EI).

[2]Cai G, Li W, Chen Y, Liu N*, Song Z, Liu QH*, 2016. Modeling and Design of a Plasmonic Sensor for High Sensing Performance and Clear Registration. IEEE Photonics Journal 8(1): 4801011, doi: 10.1109/JPHOT.2016.2520829 (IEEE: SCI/EI).

[3]Cai G, Luo M, Cai Z, Xu H, Liu QH*, 2012. A Slot-Based Surface Plasmon-Polariton Waveguide With Long-Range Propagation and Superconfinement. IEEE Photonics Journal 4(3): 844-855, doi: 10.1109/JPHOT.2012.2198914 (IEEE: SCI/EI).

[4]Cai G, Zhou M, Liu Z, Luo Z, Bu Y, Xu H, Cai Z*, Ye C, 2010. Spectroscopic analysis of Pr(3+):Gd(3)Ga(5)O(12) crystal as visible laser material. Optical Materials 33(2): 191-195, doi: 10.1016/j.optmat.2010.09.031 (SCI/EI).

[5]Liu N, Cai G, Ye L, Liu QH*, 2016. The Efficient Mixed FEM With the Impedance Transmission Boundary Condition for Graphene Plasmonic Waveguides. Journal of Lightwave Technology 34(23): 5363-5370, doi: 10.1109/JLT.2016.2613904 (IEEE: SCI/EI).

[6]Liu N, Cai G, Zhu C, Huang Y, Liu QH*, 2016. The mixed finite-element method with mass lumping for computing optical waveguide modes. IEEE Journal of Selected Topics in Quantum Electronics 22(2), 4400709, doi: 10.1109/jstqe.2015.2473689 (IEEE: SCI/EI).

[7]Liu N, Cai G, Zhu C, Tang Y, Liu QH*, 2015. The mixed spectral-element method for anisotropic, lossy, and open waveguides. IEEE Transactions on Microwave Theory and Techniques 63(10): 3094-3102, doi: 10.1109/tmtt.2015.2472416 (IEEE: SCI/EI).

[8]Song Z*, Wang W, Cai G, Liu QH, 2017. Investigation of optical spectrum properties of hexagonal boron nitride from metal to dielectric transition. Plasmonics, doi: 10.1007/s11468-017-0544-y (SCI/EI).

[9]Ye L*, Chen Y, Cai G, Liu N, Zhu J*, Song Z, Liu QH, 2017. Broadband absorber with periodically sinusoidally-patterned graphene layer in terahertz range. Optics Express 25(10): 11223-11232, doi: 10.1364/OE.25.011223 (SCI/EI).

[10]Ye L, Xiao Y, Liu Y, Zhang L, Cai G, Liu QH*, 2016. Strongly confined spoof surface plasmon polaritons waveguiding enabled by planar staggered plasmonic waveguides. Scientific Reports 6(8), doi: 10.1038/srep38528 (SCI/EI).

[11]Gu G, Zhou R*, Xu H, Cai G, Cai Z, 2016. Subsurface nano-imaging with self-assembled spherical cap optical nanoscopy. Optics Express 24(5): 4937-4948, doi: 10.1364/oe.24.004937 (SCI/EI).

[12]Gu G, Zhou R, Chen Z, Xu H, Cai G, Cai Z*, Hong M, 2015. Super-long photonic nanojet generated from liquid-filled hollow microcylinder. Optics Letters 40(4): 625-628, doi: 10.1364/ol.40.000625 (SCI/EI).

[13]Guo C, Che K, Gu G, Cai G, Cai Z, Xu H*, 2015. Tailoring the plasmonic whispering gallery modes of a metal-coated resonator for potential application as a refractometric sensor. Applied Optics 54(6): 1250-1256, doi: 10.1364/AO.54.001250 (SCI/EI).

[14]Wang X, Wang Z, Bu Y*, Chen L, Cai G, Huang W, Chen N, 2016. Power-ratio tunable dual-wavelength laser using linearly variable fabry-perot filter as output coupler. Applied Optics 55(4): 879-883, doi: 10.1364/ao.55.000879 (SCI/EI).

[15]Wang X*, Wang Z, Bu Y, Chen L, Cai G, Cai Z, 2014. A 1064-and 1074-nm dual-wavelength Nd:YAG laser using a fabry-perot band-pass filter as output mirror. IEEE Photonics Journal 6(4): 1501607, doi: 10.1109/jphot.2014.2345884 (IEEE: SCI/EI).

[16]Wang X, Wang Z, Bu Y, Liu Z, Chen L, Cai G, Dawes, J. M., 2014. A 1064 nm, 1085 nm dual-wavelength Nd:YVO4 laser using fabry-perot filters as output couplers. IEEE Photonics Technology Letters 26(19): 1983-1985, doi: 10.1109/lpt.2014.2344114 (IEEE: SCI/EI).

[17]Wang Z, Wang X*, Cai M, Bu Y, Chen L, Cai G, 2014. A linearly polarized 1123 nm Nd:YAG laser using a fabry-perot filter as output mirror. Optics Communications 330: 143-146, doi: 10.1016/j.optcom.2014.05.044 (SCI/EI).