教师名录
肖君军
通讯地址:中国深圳市南山区西丽深圳大学城哈工大校区C411
电子邮件:eiexiao AT hit.edu.cn
联系电话:(+86)-755-26032716

个人简介

欢迎物理、电子、光学、 材料、信息、通讯、计算机、仪器等相关专业、或者对linux开发和大规模并行计算有兴趣的研究生加入我们的课题组! 每年计划招收:

【1】博士生1-2名(招生专业为 电子科学与技术),提供大量出国交流和访问机会;
【2】硕士研究生4-6名 (招生专业为 物理电子学 和 光学工程), 推免生优先;
【3】博士后1-2名,博士后常年招收,待遇从优;

有意者可email 至 eiexiao@hit.edu.cn 或 xiaoxun@gmail.com,或电话直接联系!

研究方向

研究领域涉及光学、光子学、及光电子学,研究方向涵盖国际前沿基础研究和应用研究,主要包括(但不限于):

【1】光学超表面及表面等离激元光学 (Metasurface & Plasmonics):Spin-dependent optics, PT-symmetry optics......
【2】微纳光子学(Nanophotonics)及其在新一代信息技术、新型光电集成等领域的应用
【3】亚波长光电子器件(Sub-wavelength optoelectronics)及其在光通讯、光传感、及高速3D计算成像等领域的应用
【4】智能信息光学 (Smart information optics):包括亚像素自动光学检测(AOI)、机器视觉等

教育经历

2003-2006   博士, 香港中文大学, 微纳光子学
1999-2002  硕士, 兰州大学, 凝聚态物理
1995-1999   学士, 兰州大学, 半导体器件与微电子学
2004- 2005  多伦多大学光学研究所, Visiting Student , John E. Sipe Group

研究与工作经历

2015-至今  哈尔滨工业大学深圳研究生院 教授,博士生导师
2009-2015  哈尔滨工业大学深圳研究生院 副教授,博士生导师
2007-2009  香港科技大学 博士后访问学者
2006-2007  香港中文大学 博士后研究员
  
  

专业资质与学术兼职

2012-  国家自然科学基金函评专家、广东省自然科学基金函评专家
2010-  深圳市科技专家委员会评审专家
2007-  Phys. Rev. Lett. (A, B), Appl. Phys. Lett., J. Appl. Phys., IEEE Photon. Technol. Lett., Opt. Express, Opt. Lett., J. Opt. Soc. Am B, Opt. Commun. ACS Nano, Nanoscale, J. Mat. Chem. C, Sci. Rep., Supplatt and Micro., Chin. Phys. B, Chin. Opt. Lett., 《光子学报》,《中国科学》等期刊审稿人
2004-  IEEE, APS, OSA, HKPS, ETOPIM 会员
2015-  Member of Editorial Board, Heliyon -Elsevier's new open access journal (http://www.heliyon.com)

科研项目

2016-2017  深圳市基础研究项目:基于人工电磁表面的光学相干作用机理与应用研究
2015-2018  广东省自然科学基金自由申请项目: 基于表面等离激元共振结构的高抗反光学超表面研究
2013-2016  国家自然科学基金面上项目: 基于微纳光子超结构的若干量子力学-光子学类比研究
2011-2013  国家自然科学基金青年基金: 基于表面等离子体共振结构的光学微操控研究
2013-2015  深圳市孔雀计划项目
2013-2014  深圳市基础研究项目(新材料专项)
2011-2013  深圳市科技计划基础研究项目
2011-2012  哈尔滨工业大学创新科研基金
2012-2015  深圳市物联网终端关键技术重点实验室
2018-2020  深圳空天探测成像关键技术工程实验室
2018-2020  深圳市科技计划基础研究项目

科研成果及奖励

2003-  主要参与及完成项目:
1. 深圳市基础研究重点项目(2012-2014): 基于偏振编码的无线激光通信机理及关键技术研究
2. 广东省省部产学研结合项目(2010-2012): IC晶圆精密立体视觉检测仪的研制
3. HKRGC(2009--2010): Using the idea of transformation optics to manipulate waves
4. HKRGC(2007--2009): Electromagnetic fields and light induced electromagnetic forces
5. HKRGC(2006--2009): Electromagnetic resonant structures and plasmonic structures
6. HKRGC Earmarked Grant (2006--2008): Nano-optics in graded plasmonic crystals
7. HKRGC (2003--2006): First-principles approach to graded-particle composites
2012  深圳市高层次人才(地方级)
2012  深圳市海外高层次人才(B类)

发明专利

(1) 肖君军 等, 一种圆盘形核壳结构的光学微纳天线及其设计方法,发明专利(CN 104157960)
(2) 肖君军 等,一种类表面等离子体复合型狭缝波导及其应用, 发明专利(申请号:201510023376.9)
(3) 肖君军 等,一种基于金属薄膜上反结构的旋磁衬底超表面,发明专利(申请号:201610107486.8)
(4) 肖君军 等,一种微波段双层双金属线结构手征超表面,发明专利(申请号:201610311098.1)
(5) 肖君军 等,一种具有双单向性的光学纳米天线及其设计方法,发明专利(申请号:201610305167.8)
(6) 肖君军,刘真真,耦合波导阵列中的无损耗传输模式设计方法,发明专利(申请号:2017104251801)
(7) 肖君军,刘真真,一种基于极化共振和布拉格共振作用的超透射波导,发明专利(申请号:2017104240243)
(8) 肖君军,吴波等,基于多模光纤的单像素相机系统,发明专利(申请号:201710582132.3)
(9) 肖君军,姚杏枝等, 一种对AMOLED进行外部光学补偿的方法及装置,发明专利(申请号:2017107498948)
(10) 肖君军,李雄等, 一种AMOLED显示屏Mura缺陷检测方法,发明专利(申请号:2017107924574)
(11) 肖君军,张喆等,基于压缩感知理论的单像素相机视频成像系统,发明专利(申请号: 201810053080.5)


论文及著作

ResearcherID: http://www.researcherid.com/rid/B-9205-2011

====Since HITSZ======================================

【Book Chapters】:

[1] J. J. Xiao*, K. Yakubo, and K. W. Yu, "Graded plasmonic structures and their properties", Chapter in the book 《Plasmons: Theory and Applications》, Nova Science Publishers, New York, 2011 (ISBN: 978-1-61761-306-7)
(https://www.novapublishers.com/catalog/product_info.php?products_id=13151)
[2] J. J. Xiao*, Q. Zhang, Z. Z. Liu et al, "Several quantum-optical analogues in plasmonic nanostructures," Chapter in the book 《Plasmonics: Advances in Research and Application》, 2017 (ISBN:978-1-53610-174-4)
(https://www.novapublishers.com/catalog/product_info.php?products_id=59875&osCsid=2f9298bcc2eae6a16cafa48077fc8042)

【Journal Articles (SCI)】

[76] Z. Z. Liu and J. J. Xiao*, Exceptional contour around degeneracy points in PT-symmetric photonic crystals (under review).
[75] S. H. Wu, T. T. Zhang, B. Wu, C. H. Liu, and J. J. Xiao*, “Single pixel camera in the visible band with fiber signal collection,” IEEE Access (2018). https://doi.org/10.1109/ACCESS.2018.2819358
[74] X. J. Li, Y. F. Sun, X. Z. Yao, and J. J. Xiao*, “Mura defect detection based on mean shift and level set algorithm for AMOLED display panel”, Journal of Electronic Imaging (under review).
[73] X. Z. Yao, X. J. Li, and J. J. Xiao*, Subpixel-level external optical compensation for AMOLED panel based on CCD imaging. The 10th International Conference on Digital Image Processing, 2018.
[72] X. M. Zhang, Q. Zhang, S. J. Zeng, and J. J. Xiao*, "Dual-band unidirectional forward scattering with all-dielectric hollow nanodisk in the visible" Optics Letters 43(6) 1275-1278 (2018) https://doi.org/10.1364/OL.43.001275.
[71] F. F. Qin, Z. Z. Liu and J. J. Xiao*, "Broadband full-color multifunctional hologram with geometric phase metasurface", Optics Express 26(7), 2018.

[70] T. T. Zhang, B Wu, S. H. Wu, and J. J. Xiao*, “Improved Single Pixel Camera via Fiber Collecting Strategy”, International Conference on Communications, 6th International Conference on Signal Processing, and Systems (CSPS), IEEE, Harbin, (2017).
[69] Y. Meng, R. Y. Zhang, Q. Zhang, Z. Z. Liu, X. X. Wu, J. J. Xiao, H. Xiang, D. Z. Han, W. Wen, “Surface plasmon polaritons on the thin metallic film coated with symmetrical and asymmetrical dielectric gratings,” Journal of Physics D-Applied Physics 50(48), 48501 (2017).
[68] Z. Z. Liu, F. F. Qin, Q. Zhang, and J. J. Xiao*, “Complex band structure of one-dimensional polariton crystals,” Optics Express 25(22),26689-26703 (2017). https://doi.org/10.1364/OE.25.026689
[67] M. L. Li, Q. Zhang, F. F. Qin, Z. Z. Liu, Y. P. Piao, Y. Wang and J. J. Xiao*, "Microwave linear polarization rotator in a bilayered chiral metasurface based on strong asymmetric transmission," Journal of Optics 19, 075101 (2017) .
[66] X. M. Zhang, J. J. Xiao* et al.,"Dual-band unidirectional emission in multilayered metal-dielectric nanoantenna," ACS Omega 2 (3), 774–783 (2017). https://doi.org/10.1021/acsomega.7b00121
[65] Z. Z. Liu, Q. Zhang, Y. T. Chen, and J. J. Xiao*,“General coupled mode analysis of geometry symmetric waveguide array with non-uniform gain and loss,” Photonics Research 5(2), 57-63 (2017). https://doi.org/10.1364/PRJ.5.000057

[64] B. B. Wu, B. Wu, J. Xu, J. J. Xiao, and Y. T. Chen, “Coupled mode theory in non-Hermitian cavities,” Optics Express 24(15), 16566-16573 (2016). http://dx.doi.org/10.1364/OE.24.016566
[63] F. F. Qin, Q. Zhang, and J. J. Xiao*, “Sub-wavelength unidirectional antenna realized by stacked spoof localized surface plasmon resonators,” Scientific Reports 6, 29773 (2016). http://dx.doi.org/10.1038/srep29773
[62] Y. H. Li, Q. Zhang and J. J. Xiao*, "Designing commensurate and incommensurate resonances for enhanced dipole emission in coupled plasmonic nanorods," Plasmonics 11, 825-831 (2016). http://dx.doi.org/10.1007/s11468-015-0115-z
[61] Z. Z. Liu, Q. Zhang, X. Liu, Y. Yao, and J. J. Xiao*, "Absence of exceptional points in square waveguide arrays with apparently balanced gain and loss," Scientific Reports 6, 22711 (2016). http://dx.doi.org/10.1038/srep22711
[60] F. F. Qin, J. J. Xiao*, Z. Z. Liu, and Q. Zhang, “Multiple Fano-like transmission mediated by multimode interferences in spoof surface plasmon cavity-waveguide coupling system,” IEEE Transactions on Microwave Theory and Techniques 64(4),1186-1194 (2016). http://dx.doi.org/10.1109/TMTT.2016.2533381
[59] F. F. Qin, J. J. Xiao*, Q. Zhang and W. G. Liang "Multiple Fano resonances in spatially compact and spectrally efficient spoof surface plasmon resonators with composite structures," Optics Letters 41(1), 60-64 (2016). http://dx.doi.org/10.1364/OL.41.000060
[58] Z. Z. Liu, Q. Zhang and J. J. Xiao*, “EIT-like transmission by interaction between multiple Bragg scattering and local plasmonic resonances,”Journal of Optics 18, 015008 (2016). http://dx.doi.org/10.1088/2040-8978/18/1/015005
[57] B. Guo, Y. Yao, J. J. Xiao, R. L. Wang, and J. Y. Zhang “Topological insulator-assisted dual-wavelength fiber laser delivering versatile pulse patterns,” IEEE Journal of Selected Topics in Quantum Electronics 22(2), 0900108 (2016). http://dx.doi.org/10.1109/JSTQE.2015.2426951

[56] Q. Zhang, J. J. Xiao*, M. L. Li, D. Z. Han, and L. Gao, "Coexistence of scattering enhancement and suppression by plasmonic cavity modes in loaded dimer gap-antennas," Scientific Reports 5, 17234 (2015). http://dx.doi.org/10.1038/srep17234
[55] H. Xiang, Y. Meng, Q. Zhang, F. F. Qin. J. J. Xiao, D. Han, and W. J. Wen “Spoof surface plasmon polaritons on ultrathin metal strips with tapered grooves,” Optics Communications 356, 59 (2015). http://dx.doi.org/10.1016/j.optcom.2015.07.060
[54] X. M. Zhang, J. J. Xiao*, Q. Zhang, M. L. Li, and Y. Yao, "Plasmonic TM-like cavity modes and the hybridization in multilayered metal-dielectric nanoantenna," Optics Express 23(12), 16122-16132 (2015). http://dx.doi.org/10.1364/OE.23.016122
[53] Q. Zhang, J. J. Xiao*, D. Z. Han, F. F. Qin, X. M. Zhang, and Y. Yao, "Microwave band gap and cavity mode in spoof-insulator-spoof waveguide with multiscale structured surface," Journal of Physics D: Applied Physics 48, 205103 (2015). http://dx.doi.org/10.1088/0022-3727/48/20/205103
[52] Y. Huang, J. J. Xiao, and L. Gao, “Antibonding and bonding lasing modes with low gain threshold in nonlocal metallic nanoshell,” Optics Express 23(7), 8818 (2015). http://dx.doi.org/10.1364/OE.23.008818
[51] Z. Z. Liu, J. J. Xiao*, Q. Zhang, X. M. Zhang, and K. Y. Tao, “Collective dark states controlled transmission in plasmonic slot waveguide with a stub coupled to a cavity dimer," Plasmonics, 10, 1057 (2015).
http://dx.doi.org/10.1007/s11468-015-9901-x
[50] Q. Zhang, J. J. Xiao*, X. M. Zhang, D. Z. Han, and L. Gao “Core-shell structured dielectric-metal circular nanodisk antenna: gap plasmon assisted magnetic toroid-like cavity modes,” ACS Photonics 2(1), 60-65 (2015). http://dx.doi.org/10.1021/ph500229p

[49] K. Y. Tao, J. J. Xiao, and X. B. Yin, “Nonreciprical photonic crystal add-drop filter,” Applied Physics Letters 105(22), 211105 (2014). http://dx.doi.org/10.1063/1.4902868
[48] S. L. Wang, J. J. Xiao*, Q, Zhang, and X. M. Zhang, “Resonance modes in stereometamaterial of square split ring resonators connected by sharing the gap,” Optics Express, 22(20), 24359 (2014). http://dx.doi.org/10.1364/OE.22.024358
[47] X. M. Zhang, J. J. Xiao*, and Q. Zhang, “Interaction between single nano-emitter and disk-ring plasmonic nanostructure with multiple Fano resonances,” Journal of Optical Society of America B 31(9), 2193 (2014). http://dx.doi.org/10.1364/JOSAB.31.002193
[46] X. M. Zhang, J. J. Han, Q. Zhang, F. F. Qin, and J. J. Xiao*, "Plasmonic supermodes in nanocrescent dimer with tunable resonances at the near-infrared," Optics Communications 325, 9 (2014). http://dx.doi.org/10.1016/j.optcom.2014.03.078
[45] Q. Zhang, J. J. Xiao*, and S. L. Wang, "Optical characteristics associated with magnetic resonance in toroidal metamaterials of vertically coupled plasmonic nanodisks," Journal of Optical Society of America B 31(5), 1103 (2014). http://dx.doi.org/10.1364/JOSAB.31.001103
[44] Y. J. Yuan, Y. Yao, J. J. Xiao, Y. Yan, J. J. Tian, and C. Liu, "Experimental and numerical study of high order Stokes lines in Brillouin-erbium fiber laser," Journal of Applied Physics 115, 043102 (2014).
[43] X. M. Zhang, J. J. Xiao*, and Q. Zhang, "Optical binding forces between plasmonic nanocubes: A numerical study based on discrete-dipole approximation," Chinese Physics B 23, 017302 (2014). http://dx.doi.org/10.1088/1674-1056/23/1/017302

[42] Q. Zhang and J. J. Xiao*, "Multiple reversals of optical binding force in plasmonic disk-ring nanostructures with dipole-multipole Fano resonances," Optics Letters 38, 4240 (2013). http://dx.doi.org/10.1364/OL.38.004240
[41] S. B. Wang, H. H. Zheng, J. J. Xiao, Z. F. Lin, and C. T. Chan, "Fast multipole boundary element method for three dimensional electromagnetic scattering problem," International Journal of Computational Materials Science and Engineering, 01 (4), 1250038 (2013) [36 pages]. http://dx.doi.org/10.1142/S2047684112500388
[40] Q. Zhang, J. J. Xiao*, X. M. Zhang, and Y. Yao, "Optical binding force of gold nanorod dimer coupled to a metallic slab," Optics Communications 301-302, 121 (2013). http://dx.doi.org/10.1016/j.optcom.2013.04.005
[39] Q. Zhang, J. J. Xiao*, X. M. Zhang, Y. Yao, and H. Liu, "Reversal of optical binding force by Fano resoanance in plasmonic nanorod heterodimer, " Optics Express 21, 6601 (2013). http://dx.doi.org/10.1364/OE.21.006601
Selected for the Virtual Journal for Biomedical Optics, Vol. 8, Issue 4, May 2013

[38] X. L. Yu, Y. Yao, J. J. Xiao, and J. J. Tian, "A practical approach to synthesize multi-channel fiber Bragg grating with right-angled triangular spectrum," Chinese Physics Letters, 29, 114211 (2012).
[37] X. L. Yu, Y. Yao, J. J. Xiao, and J. J. Tian, "Optimal design of short fiber Bragg gratings with triangular spectrum," Optics Communications 285, 631 (2012).
[36] J. J. Tian, Y. Yao, J. J. Xiao, X. C. Xu, and D. Chen, "Tunable multiwavelength erbium-doped fiber laser based on intensity-dependent loss and intra-cavity loss modulation," Optics Communications 285, 2426 (2012).
[35] J. J. Tian, Y. Yao, J. J. Xiao, X. C. Xu, and D. Chen, "Multiwavelength Erbium doped fiber laser based on intensity dependent transmission in a linear cavity," Journal of Applied Physics 109, 113102 (2011).
[34] J. J. Tian, Y. Yao, J. J. Xiao, X. C. Xu, and D. Chen, "A triple function linear fiber laser with passive mode locking, continuous wave single- and multi-wavelength lasing," Optics Letters 36, 1509 (2011).
[33] J. J. Tian, Y. Yao, J. J. Xiao, X. C. Xu, and D. Chen, "A pump power controlled multiwavelength fiber laser with adjustable output channels at fixed wavelength," Applied Physics B: Lasers Optics 102, 545 (2011).
[32] C. Liu, et al, "Average capacity optimization in freespace optical communication system over atmospheric turbulence channels with pointing errors,” Optics Letters 35, 3171 (2010).
[31] H. H. Zheng, J. J. Xiao, Y. Lai, and C. T. Chan, "Exterior optical cloaking and illusions by using active sources: a boundary element perspective,” Physical Review B 81, 195116 (2010).
[30] J. J. Xiao*, H. H. Zheng, Y. X. Sun, and Y. Yao, "Bipolar optical forces on dielectric and metallic nanoparticles by evanescent waves,” Optics Letters 35, 962 (2010).
[Erratum: Opt. Lett. 35, 1853 (2010)]
[29] M. J. Zheng, J. J. Xiao, and K. W. Yu, "Controllable optical Bloch oscillation in planar graded optical waveguide arrays,” Physical Review A 81, 033829 (2010).
[28] M. J. Zheng, J. J. Xiao, and K. W. Yu, "Tunable localization and oscillation of coupled plasmon waves in graded plasmonic chain,” Journal of Applied Physics 106, 113307 (2009).
Selected for the January 4, 2010 issue of the Virtual Journal of Nanoscale Science & Technology.
[27] M. J. Zheng, J. J. Xiao, K. Yakubo, and K. W. Yu, "Energy relaxation in damped two dimensional graded elastic lattices,” Journal of Physics Society of Japan 78, 124603 (2009).
[26] Y. C. Jian, J. J. Xiao*, and J. P. Huang, "Optical force on dielectric nanorods coupled to a high-Q photonic crystal nanocavity,” Journal of Physical Chemistry C 113, 17170 (2009).
Media Coverage of This Work:
(1) “Nanocavity brings optical tweezing down to size”, "Photonics Spectra" Magazine News Dec. 2009, http://www.photonicsspectra-digital.com/photonicsspectra/200912?pg=18#pg18
(2) “Photonic-crystal cavities as optical nanomachines", SPIE (国际光学工程协会)Newsroom, 2009, http://spie.org/x38275.xml?highlight=x2400&ArticleID=x38275
(3) 科学时报》2010年1月19日报道, http://news.sciencenet.cn/sbhtmlnews/2010/1/228173.html。
----并获科学网,新华网, 人民网,自然科学基金委网站,中国教育科研网,中国经济网等几十个国内著名网站转载报道。
(4) "光子带来的源动力", 《南方周末》,2010年02月04日 E26科学/文学版, http://www.infzm.com/content/41130.
(5) Recommanded Paper in "Nature China" , http://spotlight.nature.com/products/nchina/subjects/physics)

===== Prior to HITSZ=================================
[25] Y. Lai, J. Ng, H. Chen, D. Z. Han, J. J. Xiao, Zhao-Qing Zhang and C. T. Chan, "Illusion optics: The optical transformation of an object into another object”, Physical Review Letters 102, 253902 (2009).
Media Coverage of This Work:
(1)“Material Witness: Dream on,” Nature Material
(2)“Optics: Swap trick,” Nature China
(3)“Modified invisibility cloak could make the ultimate illusion ”, New Scientist
(4)“Transform a ball into a rock–or make it invisible–using transformation optics,” PhysOrg.com
(5)“More illuson than invisible,” Synopsis in Physics
(6)“Illusion cloak makes one object look like another,” the physics arXiv blog
(7)“Optics: All smoke and metamaterials,” Nature 460, 579 (2009)
(8)“Magical matematerials,” Optics & Photonics Focus
(9)“‘Cloak of Illusion’ Tech Could Disguise Objects,” Discovery Channel
[24] T. H. Fung, L. L. Leung, J. J. Xiao*, and K. W. Yu, "Controlling electric fields spatially by graded metamaterials: Implication on enhanced nonlinear optical responses”, Optics Communications 282, 1028 (2009)
[23] J. J. Xiao*, J. Ng, Z. F. Lin, and C. T. Chan, "Whispering gallery mode enhanced optical force with resonant tunneling excitation in the Kretschmann geometry”, Applied Physics Letters 94, 011102 (2009)
[22] J. J. Xiao and C. T. Chan, "Calculation of the optical force on an infinite cylinder with arbitrary cross-section by the boundary element method”, Journal of Optical Society of American B, 25, 1553 (2008)
[21] J. J. Xiao*, J. P. Huang, and K. W. Yu, "Dynamic polarizability of rotating particles in electrorheological fluids”, Journal of Physical Chemistry B 112, 6767 (2008)
[20] J. J. Xiao* and K. W. Yu, "Light trapping and releasing in side-coupled microresonator structures with asymmetric cavity–waveguide coupling”, Optics Communications 281, 4023 (2008)
[19] J. J. Xiao*, K. Yakubo, and K. W. Yu, "Global phase diagram of one dimensional graded diatomic elastic chains: A diagrammatic approach to identifying vibrational normal modes”, Journal of Physics: Condensed Matter 19, 026224 (2007)
[18] S. M. Wang, J. J. Xiao*, and K. W. Yu, "Tunable coupled plasmon modes via nanoshell particle chains”, Optics Communications 279, 384 (2007)
[17] J. J. Xiao, K. Yakubo, and K. W. Yu, "Variety of normal modes and their transition behaviors in graded elastic networks: square networks with a diagonal gradient”, Journal of Physics Society of Japan 76, 024602 (2007)
[16] J. J. Xiao*, Joseph T. A. Kwok, and K. W. Yu, "Optical properties of graded colloid nanocrystallines with tunable structure”, Optics Communications 272, 252 (2006)
[15] J. J. Xiao*, K. Yakubo, and K. W. Yu, "Dispersion and transitions of dipolar plasmon modes in graded plasmonic waveguides”, Applied Physics Letters 89, 221503 (2006)
Selected for the December 11, 2006 issue of Virtual Journal of Nanoscale Science & Technology
[14] J. J. Xiao, K. Yakubo, and K. W. Yu, "Harmonic vibrations in two-dimensional graded elastic networks: Variety of normal modes and their transitions”, Physical Review B 73, 224201 (2006)
[13] J. J. Xiao, K. Yakubo, and K. W. Yu, "Optical switching in graded plasmonic waveguides”,
Applied Physics Letters 88, 241111 (2006)
Selected for the June 26, 2006 issue of Virtual Journal of Nanoscale Science & Technology.
[12] J. J. Xiao, K. Yakubo, and K. W. Yu , "Harmonic vibrational excitations in graded elastic networks: Transition from phonons to gradons”, Physical Review B 73, 054201 (2006)
[11] J. J. Xiao* and K. W. Yu, "Giant enhanced optical nonlinearity in colloid nanocrystal with a graded-index host”, Applied Physics Letters 88, 071911 (2006)
Selected for the February 27, 2006 issue of Virtual Journal of Nanoscale Science & Technology.
[10] J. J. Xiao, J. P. Huang, and K. W. Yu, "Optical response of strongly coupled metal nanoparticles in dimer arrays”, Physical Review B 71, 045404 (2005)
Selected for the January 17, 2005 issue of Virtual Journal of Nanoscale Science & Technology.
[9] Q. F. Liu, C. Z. Long, J. J. Xiao, C. X. Gao, and D. S. Xue, "Size effects on magnetic properties in Fe0.68Ni0.32 alloy nanowire arrays”, Journal of Magnetism and Magnetic Materials 260, 151 (2003)
[8] J. J. Xiao, C. Sun, D. S. Xue, and F. S. Li, "Study on magnetic properties of Fe-nanowires by micromagnetic simulation”, Acta. Physica. Sinica (in Chinese), 50, 1605 (2001)
[7] C. W. Choy, J. J. Xiao, and K. W. Yu, "Electrostatic resonances and optical responses of cylindrical clusters”, J. Phys.: Conference Series 142, 012017 (2009)
[6] K. Yakubo, J. J. Xiao , and K. W. Yu , "Localized vibrations in graded lattices: Gradons”,
J. Phys.: Conference Series 92, 012008 (2007)
[5] J. J. Xiao, K. Yakubo, and K. W. Yu, "Vibrational excitations in graded elastic chains”,
Int. J. Mod. Phys. B 21, 4184 (2007)
[4] J. J. Xiao*, K. Yakubo, and K. W. Yu, "Coupled plasmon modes and their localization in graded plasmonic chains”, Physica B: Condensed Matter 394 (2), 208 (2007)
[3] K. Yakubo, J. J. Xiao, and K. W. Yu, "Confined vibrational normal modes in graded elastic networks: gradons”, Physica B: Condensed Matter 394 (2), 262 (2007)
[2] C. W. Choy, J. J. Xiao, and K. W. Yu, "Local field distribution near corrugated interfaces: Green function formalism versus effectivemedium theory”, Physica B: Condensed Matter 394 (2), 325 (2007)
[1] K. W. Yu, G. Q. Gu, J. P. Huang, and J. J. Xiao, "Dynamic electrorheological effects of rotating particles: a brief review”, Int. J. Mod. Phys. B 19, 1163 (2005)


会议论文及发表演说

[1] J. J. Xiao*. Toroidal cavity resonances in metal-dielectric-metal nanoantenna, META17, Seoul, Korea, 2017
[2] F. F. Qin and J. J. Xiao*. Metasurface holograms based on multi-layered chiral nanostructures, PIERS 2017, St. Petersburg, Russia, 2017.
[3] Z. Z. Liu and J. J. Xiao*. General analysis of the indispensable effects of nonuniform gain and loss in coupled waveguides system. PIERS 2017, St. Petersburg, Russia, 2017.
[4] J. J. Xiao*. Coalescence of exceptional points and phase diagrams of PT-symmetric polariton crystal. PIERS 2017, St. Petersburg, Russia, 2017.
[5] Z. Z. Liu and J. J. Xiao*. Lossless coupled modes in symmetric waveguide array with non-uniform gain and loss. Photonics Asia, Beijing, China, 2016.
[6] F. F. Qin and J. J. Xiao*. Unidirectional antenna realized by spoof localized surface plasmon resonators. Photonics Asia, Beijing, China, 2016.
[7] X. M. Zhang and J. J. Xiao*. Controllable unidirectional emission of electric dipole coupled to plasmonic bowtie antenna. Photonics Asia, Beijing, China, 2016.
[8] Q. Zhang, Liu Z Z, and J. J. Xiao*. Spin-orbital interaction of surface plasmon polaritons with different spin angular momentum locking features. PIERS, Shanghai, China, 2016.
[9] F. F. Qin and J. J. Xiao*. Unidirectional RF antenna by stacked spoof surface plasmon pesonators. PIERS, Shanghai, China, 2016.
[10] Z. Z. Liu and J. J. Xiao*. Absence and recovery of exceptional points in coupled waveguides with complex conjugate distribution of refractive index. PIERS, Shanghai, China, 2016.
[11] Z. Z. Liu and J. J. Xiao*. Transmission of plasmonic waveguide modulated by side-coupled resonators: theoretical analysis and numerical simulation. PIERS, Shanghai, China, 2016.
[12] J. J. Xiao*, 2016 第三届全国光电材料、器件及发展趋势研讨会, 贵阳, 2016
[13] Q. Zhang and J. J. Xiao*. Exciting surface waves unidirectionally by coherent localized dipolar soruces. CIOP, Shanghai, China, 2016.
[14] Z. Z. Liu and J. J. Xiao*. Exceptional Point Annihilation and Lossless Coupled Modes in Coupled Waveguide Array. CIOP, Shanghai, China, 2016.
[15] J. J. Xiao*, “Several quantum-optical analogies in coupled nanoantenna, waveguide and metasurface,” IAS Workshop “Advanced concepts in wave physics: Topology and parity-time symmetries” HKUST, Jan.1-15, 2016.
[16] J. J. Xiao*, “Multiscale structured ultrathin metal surface for microwave manipulation by spoof surface plasmon polariton,” EMN Hong Kong Meeting, Dec. 12-15, 2015, Hong Kong.
[17] J. J. Xiao*, Q. Zhang, D. Han, and L. Gao, “Fano resonance induced by magnetic toroidal moment in hybrid plasmonic-dielectric nanostructures,” The 6th International Conference on Metamaterials, Photonic Crystals and Plasmonics (Meta 2015), 4-7 August, New York.
[18] Q. Zhang, Z. Z. Liu, H. Xiang, D. Han, and J. J. Xiao*,”Wave manipulation by coupled cavities in structured metallic surface,” The 6th International Conference on Metamaterials, Photonic Crystals and Plasmonics (Meta 2015), 4-7 August, New York.
[19] J. J. Xiao*, Q. Zhang, X. M. Zhang, and F. F. Qin, “Fano effects induced by toroidal resonances in hybrid plasmonic-dielectric nanostructures,” International Photonics and Opto-Electronics Meeting (POEM), Organized by the Optical Society of America, June 16-19, Wuhan, 2015. (EI收录)
[20] Z. Z. Liu and J. J. Xiao*, “Double electromagnetically induced transparency in a metal-dielectric-metal plasmonic waveguide system composed of cascaded resonators,” International Photonics and Opto-Electronics Meeting (POEM), Organized by the Optical Society of America, June 16-19, Wuhan, 2015. (EI收录)
[21] F. F. Qin and J. J. Xiao*, “Multimode temporal coupled mode theory for spoof surface plasmon cavity-waveguide coupling systems,” International Photonics and Opto-Electronics Meeting (POEM), Organized by the Optical Society of America, June 16-19, Wuhan, 2015. (EI收录)
[22] J. J. Xiao*, Q. Zhang, D. Han, and L. Gao, “Magnetic toroidal dipole and toroid-like modes in hybrid plasmonic-dielectric resonator,” The 7th International Conference on Surface Plasmon Photonics (SPP7), May 31-June 5, 2015, Jerusalem, Israel.
[23] Q. Zhang, X.Hong, D. Han and J. J. Xiao*, “Spoof surface plasmon polaritons in multiscale microsructured slot waveguide,” The 7th International Conference on Surface Plasmon Photonics (SPP7), May 31-June 5, 2015, Jerusalem, Israel.
[24] J. J. Xiao*, “Interplay between Fano resonance and toroidal resonance in plasmonic-dielectric nanostructures,”, EMN Meeting on optoelectronics, April 24-27, 2015, Beijing, China
[25] Q. Zhang, S. L. Wang, F. F. Qin, and J. J. Xiao*, “Magnetic toroidal moment in coupled plasmonic nanodisks and their properties,” The 35th PIERS, Guangzhou, 25-28 August, 2014.
[26] X. M. Zhang, Q. Zhang, F. F. Qin, and J. J. Xiao*,”Emission of a point dipole mediated by multiple Fano resonances in plasmonic nanostructures”, The 35th PIERS, Guangzhou, 25-28 August, 2014.
[27] Q. Zhang, J. J. Xiao*, and L. Gao, “Gap surface plasmon polariton assisted magnetic toroidal modes in core-shell nanodisk antenna”, International Photonics and Opto-Electronics Meeting (POEM), Organized by the Optical Society of America, June 18-21, Wuhan, 2014. (EI收录)
http://dx.doi.org/10.1364/OEDI.2014.OF5A.3
[28] J. J. Xiao*, Q. Zhang, X. M. Zhang, and F. F. Qin, “Negative optical binding force induced by Fano resonances in plasmonic heterodimers”, The 35th PIERS, Guangzhou, 25-28 August, 2014.
[29] Q. Zhang, J. J. Xiao*, and L. Gao, “Gap surface plasmon polariton assisted magnetic toroidal modes in core-shell nanodisk antenna”, International Photonics and Opto-Electronics Meeting (POEM), Organized by the Optical Society of America, June 18-21, Wuhan, 2014. (EI收录)
[30] Q. Zhang, F. F. Qin, X. M. Zhang, and J. J. Xiao*, "Optical forces mediated by hybrid resonance in strongly coupled plasmonic nanostructures," The 11th International Symposium on Photonics and Electromagnetic Crystal Structures (PECS-XI), Shanghai, May 11-15, 2014.
[31] J. J. Xiao*, "Plasmonic nanostructures with multiple Fano resonances and their unusual optical force effects," 中国物理学会秋季会议,厦门大学,厦门,2013
[32] 张小明 肖君军*, "任意光束下三维任意形状纳米颗粒的散射及光力特性", 中国物理学会秋季会议,厦门大学,厦门,2013
[33] Q. Zhang and J. J. Xiao*, "微纳结构中表面等离激元共振耦合导致的光力效应", 中国物理学会秋季会议,厦门大学,厦门,2013
[34] X. M. Zhang, Q. Zhang, and J. J. Xiao*, "Tractor beams to pull plasmonic nanoparticles of arbitrary shape: A numerical study based on DDA," International Workshop "Photonics of Functional Nanomaterials" 6-9 May 2013, Hong Kong
[35] Q. Zhang, X. M. Zhang, and J. J. Xiao*, "Plasmonic nanostructures with Fano resonances and their unusual optical force effect," International Workshop "Photonics of Functional Nanomaterials" 6-9 May 2013, Hong Kong
[36] J. J. Xiao*, Croucher ASI on New Materials and New Concepts for Controlling Light and Waves, HKUST, Hong Kong, 2012.
[37] 肖君军,”微纳颗粒近场光学微操控数值计算”,中国物理学会秋季会议,中山大学,广州, 2012
[38] J. J. Xiao*, Workshop on the Frontiers of Plasmonics and Related Nanophotonics, CUHK, Hong Kong, May 20-23, 2011.
[39] J. J. Xiao*, Workshop on Optics and New Materials II, CUHK, Hong Kong, April 30- May 3, 2010.

任教和任导师经历

讲授课程  《信息光学》、《信息光子学》、《量子电子学》

指导研究生  已毕业硕士生21人,大部分任职于中兴、华为、爱立信等IT公司以及光电高新企业
在读博士4人(1人毕业海外深造),硕博连读1人,硕士生6人; 在站博士后3人

指导学生获奖
(1) 张强(博13),2013年中国物理学会秋季会议“优秀张贴论文”奖
(2) 张强(博13),深圳市光学会2013春季论坛“优秀论文”一等奖
(3) 张强(博13),深港澳博士生学术论坛二等奖
(4) 张强(硕10),深圳市光学会2012春季论坛“优秀报告奖”
(5) 王茹(硕12),第六届光学方法高级研讨会(国际会议)“最佳论文奖”
最后更新:2018-03-24 16:44:17