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陈树琪

光学

个人资料

  • 部门: 物理学院
  • 性别:
  • 出生年月:
  • 专业技术职务: 教授
  • 研究标签:
  • 毕业院校:
  • 学位: 博士
  • 学历:
  • 联系电话: 010-62325064
  • 电子邮箱: schen@nankai.edu.cn
  • 办公地址: 物理学院 5教315室/泰达应用物理研究院 7区423室
  • 通讯地址:
  • 邮编:
  • 传真: 022-66229310

教育经历

2007/09 – 2009/04 美国亚利桑那大学 光学中心 联合培养博士 

2003/09 – 2009/06 南开大学 物理科学学院 博士         

1999/09 – 2003/06 天津大学 理学院 学士         

工作经历

2016/12 - 至今    南开大学 物理科学学院/泰达应用物理研究院 教授 博士生导师

2015/03 - 2018/02 国家自然科学基金委员会 数理科学部 物理一处 流动项目主任

2011/12 - 2016/12 南开大学 物理科学学院/泰达应用物理研究院 副教授 博士生导师(2014/12至今)

2009/07 –2011/12 南开大学 物理科学学院/泰达应用物理研究院 讲师                             

个人简介

[个人主页:http://chenlab.nankai.edu.cn]   陈树琪博士,南开大学物理科学学院教授,博士生导师,长期从事人工微结构光场和声场多维调控及其应用、新型光场的产生及其应用和非线性光学等研究,近年来在Light: Sci. & Appl.、Adv. Mater.、Adv. Funct. Mater.、Phys. Rev. Appl.、ACS Photonics、Adv. Opt. Mater.、Appl. Phys. Lett.、Opt. Lett.等期刊发表文章60余篇,应邀为书籍《Metamaterials - Devices and Advanced Applications》撰写章节,应邀在国际和国内重要学术会议做特邀报告二十余次。2013年入选教育部“新世纪优秀人才支持计划2014年入选南开大学百名青年学科带头人培养计划,2016年入选天津市“131”创新型人才培养工程,2017年应邀担任中国激光杂志社青年编辑委员会常务委员,2017年担任国际学术期刊《American Journal of Optics and Photonics》编委,2018年应邀为《中国科学》英文版组织Metasurface Optics方向专题,20132017年指导“挑战杯”竞赛获国家二等奖、天津市特等奖和优秀指导教师等,指导的研究生多次获南开十杰、王大珩奖学金和国家奖学金。

研究领域

个人主页:http://chenlab.nankai.edu.cn/


人工微纳结构材料作为一种新的材料设计理念,已开始为越来越多的学者所关注。它的出现会给人们在世界观层面上带来的冲击,人们可以在不违背基本的物理学规律的前提下,人工获得与自然界中的物质具有迥然不同的超常物理性质的“新物质”。迄今发展出的人工微纳结构材料多与电、磁、光、声性质相联系,为信息元件的新突破提供了一个新契机。同时,人工微纳结构材料也在军事领域具有非常广阔的应用领域,它已被评为美国国防部2013-2017年科技发展“五年计划”中重点关注的六大颠覆性基础研究领域之一。Science 杂志也分别在2003年和2006年评选此人工材料为“十大科学进展”。


我们课题组针对人工微纳结构材料在超材料、纳米光子学和纳米光学器件等领域进行深入研究。

1. 超材料

超材料是指自然界不存在的、人工制造的、具有周期性结构的三维复合材料,其研究近几年来迅速成为电磁学、物理学、材料科学等学科的前沿交叉领域。超材料通常应具有以下三个特点:(1)具有新奇人工结构的复合材料;(2)具有超常的物理性质;(3)性质往往不主要取决于其构成材料的本征性质,而主要取决于其人工结构。这些微纳尺度下的人工材料可以等同的看做为自然材料中的原子和分子。通过对这种“人工原子和分子”的设计使得超材料将具备超常的材料特性。超材料在光纤、隐身材料、超级透镜、负折射材料等方面有着广泛的应用和发展前景。本课题组主要关注于利用超材料实现人工吸光材料、折射率梯度渐变材料的研究。

超材料一个引人瞩目的应用领域是电磁波“完美吸收器”,完美吸收器的概念最早是在2008年提出,这是一种基于超材料的电磁谐振吸收器,通过合理设计器件 的物理尺寸及材料参数,能够与入射电磁波的电磁分量产生耦合,从而对入射到吸收器的特定频带内的电磁波实现百分之百的吸收。目前,完美吸收器的潜在应用包 括测辐射热仪,电磁隐身,热发射等领域。更重要的是,通过尺度优化,基于超材料的新型器件在太赫兹波段也能产生有效响应,所以基于超材料的太赫兹吸收器也受到了很高的关注。


超材料可以设计出的一种折射率梯度渐变材料,其可以很大程度上提高了人类对光操控的自由度。这种超材料在很大范围上可以实现位置依赖的相位梯度分布。由于在表面引入了等效折射率梯度变化,入射角、反射角和折射角之间的关系将突破了经典的斯涅耳定律。即使在入射光角度固定的前提下仅仅需要改变材料等效折射率的梯度值,也可以简单操控透射光的方向。不仅如此,通过对材料的设计,几乎可以获得任意的等效折射率分布。与那些需要依靠逐渐相位积累来实现塑造波前的传统光学器件相比,这种梯度渐变超材料将具有更加丰富的光学性质,在超分辨成像、平面透镜、全息等领域有着非常好的发展前景。


2. 纳米光子学

纳米光子学是研究在纳米尺度上光与物质相互作用的科学与技术,在纳米尺度上实现对光子的操纵是纳米光子学的研究目标。纳米光子学不仅为研究在小于光波长的尺度上光与物质的相互作用过程提供富有挑战性的机遇,同时为在更小尺度上的光学制造技术开辟了一条新的途径。作为一个新的前沿领域,纳米光子学已经引起了世界范围内的广泛关注和极大兴趣。对于超材料这种微纳人工材料,其结构单元的尺度远小于入射光的波长,因此其提供了一个理想的平台来实现对纳米光子学的研究。本课题组利用超材料在微纳尺度下分别实现了光偏振操控以及光不对易透过。

在应用光学的诸多领域,实现对光的偏振态的调控一直是人们研究的焦点。特别是在可见光波段,许多光学现象都与光的偏振态有着密切的联系。超材料作为一种新型的人工合成材料,它利用表面等离子体激元极大地提高了我们对于光的调控能力。同时,通过在微结构关键部位添加非线性材料,温敏材料等,实现对光的偏振态的动态调控。



互逆的传播方向上传播,透射光能量的区别被称为非对称透射。由于非对称透射在构建电磁 器件方面具有很大的潜力,近来其已经成为研究的热点。我们提出了一种在近红外波段实现线偏光宽带类二极管非对称透射的杂化超材料。这一研究成果为类二极管单向透射装置的设计提供了有用的分析和新的可能性。


3. 纳米光学器件

高速发展的信息工业对光学器件集成度的要求越来越高,这促使了人们不断探索能够突破器件尺寸极限的途径。随着对纳米光子学的深入研究,纳米光学器件也应运而生。纳米光学材料可以实现快速的光子动力学过程和电信号的结合,因此它被认为是下一代的超快速和超紧凑光子电路。目前,人们已经证明了利用纳米光学技术可以实现一些重要的光学器件,包括等离子发生器,光学开关、空间光调制器等。此外,人们也一直在努力将纳米光学器件应用于生物医学传感,近场显微镜和光谱能量收集等领域。我们也对等离子杂化,光电信号转换以及基于纳米光学器件的光信息传输与加密等领域具有浓厚的研究兴趣。

4. 声学器件

声波与电磁波之间有一定的对应关系,比如声质量密度与介电常数对应、声体弹性模量与磁导率的倒数对应,因此许多光学现象一样可以在声学中实现,比如说超材料、超透镜和声学隐身等概念同样可以类比到声学中来。声学还有它独到之处,一些在微观尺度下光学、电子学不容易观测的现象可以在宏观的声学系统中观测到,这使声学成为了人们探索物理机制的一个重要手段。随着超声成像和诊断、弱声探测和噪音控制等声学需求的逐渐增加,最近几年,相应的声学器件也在飞速发展,其中超透镜、完美吸收器、声二极管和循环器等受到了顶尖期刊的关注。Nature的评论人指出,声二极管的发明有着与电二极管相似的重大意义,极大地促进了声子学的发展。


5. 声学调控

近年来,声子晶体和声学超材料得到了飞速的发展。与光子晶体和电磁超材料类似,声子晶体和声学超材料可以极大地拓展人们对声波的调控手段。通过对声结构的排布设计尤其是超表面的设计,可以实现声波前的控制,其中包括异常反射和透射现象、聚焦与成像、特殊声束产生等,在声源设计、超声探测和声镊操纵等领域有重大的应用价值。在声结构中引入如压电薄膜等动态调控部件对声音进行动态调制,可以更加拓展声调控的实用性。


教学工作

课程名称:基础物理实验 本科课程
课程名称:光学和光子学前沿讲座(等离子激元光学部分)研究生课程

科研项目

1、973课题南开部分,空间结构光场与微结构的线性和非线性耦合效应,2012.1-2016.12

2、国家自然科学基金,梯度渐变超材料光学特性调控及其应用研究,2014.1-2017.12

3、教育部新世纪优秀人才,基于新结构、新机理的超材料光学特性研究,2014.1-2016.12

4、南开大学百名青年学科带头人培养计划,等离子激元超表面光学特性调控,2014.11-2018.11

5、天津市自然基金,动态调控杂化超材料等离子激元诱导透明及其应用,2013.4-2016.3

6、国家自然科学基金,微结构光纤表面等离子体谐振和局域场增强及其应用研究,2011.1-2013.12

7、教育部博士点,基于微结构光纤的表面等离子体谐振及其应用研究,2011.1-2013.12

论文著作

(*代表通讯作者,发表文章原文可以从http://chenlab.nankai.edu.cn/publications.htm下载


2018年


70. Jiuyang Lu, Chunyin Qiu*, Weiyin Deng, Xueqin Huang, Feng Li, Fan Zhang, Shuqi Chen*, and Zhengyou Liu*, “Valley topological phases in bilayer sonic crystals,” Phys. Rev. Lett. 120, 116802 (2018).


69. Wenwei Liu, Zhancheng Li, Hua Cheng, Chengchun Tang, Junjie Li, Shuang Zhang, Shuqi Chen*, and Jianguo Tian, “Metasurface enabled wide-angle Fourier lens,” Adv. Mater. 30, 1706368 (2018).


68. Zhangren Zhang, Dandan Wen, Chunmei Zhang, Ming Chen, Wei Wang, Shuqi Chen, and Xianzhong Chen, “Multifunctional light sword metasurface lens,” ACS Photonics, In Press, (2018).


67. Shuqi Chen*, Zhi Li, Yuebian Zhang, Hua Cheng, and Jianguo Tian, “Phase manipulation of electromagnetic waves with metasurfaces and its applications in nanophotonics,” Adv. Opt. Mater. 6, 1800104 (2018). (Invited Review)


66. Dandan Wen, Fuyong Yue, Wenwei Liu, Shuqi Chen*, and Xianzhong Chen*, “Geometric metasurfaces for ultrathin optical devices,” Adv. Opt. Mater. 6, 1800348 (2018).(Invited Review)


65. Ruizhi Zuo, Wenwei Liu, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Breaking  the diffraction limit with radially polarized light based on dielectric  metalenses ,” Adv. Opt. Mater., In Press (2018).


64. Bo Yang, Wenwei Liu, Zhancheng Li, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Polarization-sensitive structural colors with hue-and-saturation tuning based on all-dielectric nanopixels,” Adv. Opt. Mater. 6, 1701009 (2018).


63. Chao Wang, Wenwei Liu, Zhancheng Li, Hua Cheng, Zhi Li, Shuqi Chen*, and Jianguo Tian, “Dynamically tunable deep sub-wavelength high-order anomalous reflection using graphene metasurfaces,” Adv. Opt. Mater. 6, 1701047 (2018).


62. Yuebian Zhang, Wenwei Liu, Zhancheng Li, Zhi Li, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “High-Quality-Factor multiple Fano resonances for refractive index sensing,” Opt. Lett. In Press, (2018).



2017年


61. Boyang Xie, Kun Tang, Hua Cheng, Zhengyou Liu, Shuqi Chen*, and Jianguo Tian, “Coding acoustic metasurfaces,” Adv. Mater. 29, 1603507 (2017).


60. Wenwei Liu, Zhancheng Li, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Momentum analysis for metasurfaces,” Phys. Rev. Appl. 8, 014012 (2017).


59. Boyang Xie, Hua Cheng, Kun Tang, Zhengyou Liu, Shuqi Chen*, and Jianguo Tian, “Multi-band asymmetric transmission of airborne sound by coded metasurfaces,” Phys. Rev. Appl. 7, 024010 (2017).


58. Zhaocheng Liu, Zhancheng Li, Zhe Liu, Hua Cheng, Wenwei Liu, Chengchun Tang, Changzhi Gu, Junjie Li, Hou-Tong Chen, Shuqi Chen*, and Jianguo Tian, “Single-layer plasmonic metasurface half-wave plates with wavelength-independent conversion angle,” ACS Photonics 4, 2061 (2017).


57. Jianxiong Li, Ping Yu, Chengchun Tang, Hua Cheng, Junjie Li, Shuqi Chen*, and Jianguo Tian, “Bidirectional perfect absorber using free substrate plasmonic metasurfaces,” Adv. Opt. Mater. 5, 1700152 (2017).


56. Zhancheng Li, Wenwei Liu, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Manipulation of the photonic spin Hall effect with high efficiency in gold-nanorod-based metasurfaces,” Adv. Opt. Mater. DOI: 10.1002/adom.201700413 (2017).


55. Hua Cheng, Xiaoyun Wei, Ping Yu, Zhancheng Li, Zhe Liu, Junjie Li, Shuqi Chen*, and Jianguo Tian, “Integrating polarization conversion and nearly perfect absorption with multifunctional metasurfaces,” Appl. Phys. Lett. 110, 171903 (2017).


54. Yuebian Zhang, Wenwei Liu, Zhancheng Li, Hua Cheng, Yanbang Zhang, Guozhi Jia, Shuqi Chen*, and Jianguo Tian, “Ultrathin polarization-insensitive wide-angle broadband near-perfect absorber in the visible regime based on few-layer MoS2 films,” Appl. Phys. Lett. 111, 111109 (2017).


53. Zhancheng Li, Wenwei Liu, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Spin-selective transmission and devisable chirality in two-layer metasurfaces,” Sci. Rep. 7, 8204 (2017).


52. Zhi Li, Wenwei Liu, Zhancheng Li, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Fano-resonance-based mode-matching hybrid metasurface for enhanced second-harmonic generation,” Opt. Lett. 42, 3117 (2017).


51. Zhe Liu, Shuo Du, Ajuan Cui, Zhancheng Li, Yuancheng Fan, Shuqi Chen, Wuxia Li, Junjie Li, and Changzhi Gu, “High-quality-factor mid-infrared toroidal excitation in folded 3D metamaterials,” Adv. Mater. 29, 1606298 (2017)


2016年


50. Shuqi Chen*, Wenwei Liu, Zhancheng Li, Hua Cheng, and Jianguo Tian, “Polarization State Manipulation of Electromagnetic Waves with Metamaterials and Its Applications in Nanophotonics,” Book chapter in Metamaterials - Devices and Advanced Applications, IN-TECH, ISBN:978-953-51-4926-2,(2016).


49. Ping Yu, Jianxiong Li, Chengchun Tang, Hua Cheng, Zhaocheng Liu, Zhancheng Li, Zhe Liu, Changzhi Gu, Junjie Li, Shuqi Chen*, and Jianguo Tian, “Controllable optical activity with non-chiral plasmonic metasurfaces,” Light: Science & Applications, 5, e16096 (2016).


48. Jianxiong Li, Ping Yu, Hua Cheng, Wenwei Liu, Zhancheng Li, Boyang Xie, Shuqi Chen*, and Jianguo Tian, “Optical polarization encoding using graphene-loaded plasmonic metasurfaces,” Adv. Opt. Mater.4, 91 (2016).[Inside Front Cover]


47. Jieying Liu, Zhancheng Li, Wenwei Liu, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “High-efficiency mutual dual-band asymmetric transmission of circularly polarized waves with few-layer anisotropic metasurfaces,” Adv. Opt. Mater. 4, 2028 (2016).


46. Zhi Li, Hua Cheng, Zhaocheng Liu, Shuqi Chen*, and Jianguo Tian, “Plasmonic Airy beam generation by both phase and amplitude modulation with metasurfaces,” Adv. Opt. Mater. 4, 1230 (2016).


45. Zhancheng Li, Wenwei Liu, Hua Cheng, Jieying Liu, Shuqi Chen*, and Jianguo Tian, “Simultaneous generation of high-efficiency broadband asymmetric anomalous refraction and reflection waves with few-layer anisotropic metasurface,” Sci. Rep. 6, 35485 (2016).


44. Zhancheng Li, Wenwei Liu, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Tunable dual-band asymmetric transmission for circularly polarized waves with graphene planar chiral metasurfaces,” Opt. Lett. 13, 3142 (2016).

43. Zhaocheng Liu, Shuqi Chen*, Hua Cheng, Zhancheng Li, Wenwei Liu, and Jianguo Tian, “Interferometric control of signal light intensity by anomalous refraction with plasmonic metasurface,” Plasmonics, 11,353 (2016).




2015年


42. Hua Cheng, Zhaocheng Liu, Shuqi Chen*, and Jianguo Tian, “Emergent functionality and controllability in few-layer metasurfaces,” Adv. Mater. 27, 5410 (2015).


41. Zhaocheng Liu, Zhancheng Li, Zhe Liu, Jianxiong Li, Hua Cheng, Ping Yu, Wenwei Liu, Chengchun Tang, Changzhi Gu, Junjie Li, Shuqi Chen*, and Jianguo Tian, “High performance broadband circularly polarized beam deflector by mirror effect of multi-nanorod metasurfaces,” Adv. Funct. Mater. 25, 5428 (2015). [Support Infomation][Inside Back Cover]


40. Jianxiong Li, Shuqi Chen*, Haifang Yang, Junjie Li, Ping Yu, Hua Cheng, Changzhi Gu, Hou-Tong Chen, and Jianguo Tian, “Simultaneous control of light polarization and phase distributions using plasmonic metasurfaces,” Adv. Funct. Mater. 25, 704 (2015).[Support Infomation] [Back Cover]


39. Hua Cheng, Shuqi Chen*, Ping Yu, Wenwei Liu, Zhancheng Li, Jianxiong Li, Boyang Xie, and Jianguo Tian, “Dynamically tunable broadband infrared anomalous refraction based on graphene metasurfaces,” Adv. Opt. Mater. 3,1744 (2015).[Frontispiece]


38. Zhancheng Li, Wenwei Liu, Hua Cheng, Shuqi Chen*, and Jianguo Tian, “Realizing broadband and invertible linear-to-circular polarization converter with ultrathin single-layer metasurface,” Sci. Rep. 5, 18106 (2015).


37. Wenwei Liu, Shuqi Chen*, Zhancheng Li, Hua Cheng, Ping Yu, Jianxiong Li, and Jianguo Tian, “Realization of broadband cross-polarization conversion in transmission mode in the terahertz region using a single-layer metasurface,” Opt. Lett. 40, 3185 (2015).


36. Ping Yu, Shuqi Chen*, Jianxiong Li, Hua Cheng, Zhancheng Li, Wenwei Liu, Boyang Xie, Zhaocheng Liu, and Jianguo Tian,  “Generation of vector beams with arbitrary spatial variation of phase and linear polarization using plasmonic metasurfaces,” Opt. Lett.40, 3229 (2015).


35. Zhancheng Li, Shuqi Chen*, Wenwei Liu, Hua Cheng, Zhancheng Liu, Jianxiong Li, Ping Yu, Boyang Xie and Jianguo Tian, “High performance broadband asymmetric polarization conversion due to polarization-dependent reflection,” Plasmonics 10, 1703 (2015).


34. Ping Yu, Shuqi Chen*, Jianxiong Li, Hua Cheng, Zhancheng Li, Wenwei Liu,and Jianguo Tian, “Dynamically tunable plasmonic lens between the near and far fields based on composite nanorings illuminated with radially polarized light,” Plasmonics 10, 625 (2015).



2014年


33. Zhancheng Li, Shuqi Chen*, Chengchun Tang, Wenwei Liu, Hua Cheng, Zhe Liu, Jianxiong Li, Ping Yu, Boyang Xie, Zhaocheng Liu, Junjie Li, and Jianguo Tian, “Broadband diodelike asymmetric transmission of linearly polarized light in ultrathin hybrid metamaterial,” Appl. Phys. Lett. 105, 201103 (2014).

32. Zhaocheng Liu, Shuqi Chen*, Jianxiong Li, Hua Cheng, Zhancheng Li, Wenwei Liu, Ping Yu, Ji Xia, and Jianguo Tian, “Fully interferometric controllable anomalous refraction efficiency using cross-modulation with plasmonic metasurfaces,” Opt. Lett. 39, 6763 (2014).

31. Xiaoyang Duan, Shuqi Chen*, Wenwei Liu, Hua Cheng, Zhancheng Li, and Jianguo Tian, “Polarization-insensitive and wide-angle broadband nearly perfect absorber by tunable planar metamaterials in the visible regime,” J. Opt. 16, 125107 (2014).


2013年


30. Hua Cheng , Shuqi Chen*, Ping Yu , Jianxiong Li, Boyang Xie, Zhancheng Li, and Jianguo Tian, “Dynamically tunable broadband mid-infrared cross polarization converter based on graphene metamaterial,” Appl. Phys. Lett. 103, 223102 (2013).

29. Hua Cheng , Shuqi Chen*, Ping Yu, Xiaoyang Duan, Boyang Xie, and Jianguo Tian, “Dynamically tunable plasmonically induced transparency in periodically patterned graphene nanostrips,” Appl. Phys. Lett. 103, 203112 (2013).

28. Hua Cheng, Shuqi Chen*, Ping Yu, Jianxiong Li, Li Deng, and Jianguo Tian, “Mid-infrared tunable optical polarization converter composed of asymmetric graphene nanocrosses,” Opt. Lett. 38, 1567 (2013).

27. Xiaoyang Duan, Shuqi Chen*, Hua Cheng, Zhancheng Li, and Jianguo Tian, “Dynamically tunable plasmonically induced transparency by planar hybrid metamaterial,” Opt. Lett. 38, 483 (2013).

26. Ping Yu, Shuqi Chen*, Jianxiong Li, Hua Cheng, Zhancheng Li, and Jianguo Tian, “Co-enhancing and -confining the electric and magnetic fields of the broken-nanoring and the composite nanoring by azimuthally polarized excitation,” Opt. Express 21, 20611 (2013).

25. Jianxiong Li, Shuqi Chen*, Ping Yu, Hua Cheng, Xiaoyang Duan, and Jianguo Tian, “Realization of near-field linear nano-polarizer by asymmetric nanoaperture and bowtie nanoantenna,” Opt. Express 21, 10342 (2013).

24. Jianxiong Li, Shuqi Chen*, Ping Yu, Hua Cheng, Lunjie Chen, and Jianguo Tian, “Indirectly Manipulating Nanoscale Localized Fields of Bowtie Nanoantennas with Asymmetric Nanoapertures,” Plasmonics 8, 495 (2013).


2012年


23. Xiaoyang Duan, Shuqi Chen*, Haifang Yang, Hua Cheng, Junjie Li, Wenwei Liu, Changzhi Gu, and Jianguo Tian, “Polarization insensitive and wide-angle plasmonically induced transparency by planar metamaterials in the near infrared regime,” Appl. Phys. Lett. 101, 143105 (2012).

22. Hua Cheng, Shuqi Chen*, Haifang Yang, Junjie Li, Xin An, Changzhi Gu and Jianguo Tian, “A polarization insensitive and wide-angle dual-band nearly perfect absorber in the infrared regime,” J. Opt. 14, 085102 (2012).

21. Hai Lu, Chunhua Xue, Yonggang Wu, Shuqi Chen, Xiaoliang Zhang, Haitao Jiang, Jianguo Tian and Hong Chen, “Enhanced nonlinear optical response of a planar thick metal film combined with a truncated photonic crystal,” Opt. Commun. 285, 5416 (2012).

20. Yan Li, Yudong Li, Weike Shi, Shuqi Chen,Guangzi Zhang, Zhibo Liu, Qian Sun, and Jianguo Tian, “Periodic microstructures fabricated by multiplex interfering femtosecond laser beams on graphene sheet,” Int. J. Nanomanufacturing 8, 221 (2012).


2011年


19. Shuqi Chen, Hua Cheng, Haifang Yang, Junjie Li, Xiaoyang Duan, Changzhi Gu and Jianguo Tian, “Polarization insensitive and omnidirectional broadband near perfect planar metamaterial absorber in the near infrared regime,” Appl. Phys. Lett. 99, 253104 (2011).

18. Jianxiong Li, Shuqi Chen*, Ping Yu, Hua Cheng, Wenyuan Zhou, and Jianguo Tian, “Large enhancement and uniform distribution of optical near field through combining periodic bowtie nanoantenna with rectangular nanoaperture array,” Opt. Lett. 36, 4014 (2011).

17. Shuqi Chen, Wenyuan Zhou, Zubin Li, Zhibo Liu and Jianguo Tian, “Study on Z-scan characteristics for light-tunneling heterostructures composed of one-dimensional photonic band gap material and metallic film,” J. Electromagnet. Waves. 25, 97 (2011).

16. Xin Liu, Shuqi Chen, Weiping Zang and Jianguo Tian, “Triple-layer guided-mode resonance Brewster filter consisting of a homogenous layer and coupled gratings with equal refractive index,” Opt. Express 19, 8233 (2011).

15. Lin Han, Shuqi Chen, Axel Schülzgen, Yong Zeng, Feng Song, Jianguo Tian and Nasser Peyghambarian, “Calculation and optimization of electromagnetic resonances and local intensity enhancements for plasmon metamaterials with sub-wavelength double-slots,” Prog. Electromagn. Res. 113, 161 (2011).

14. Xin Liu, Shuqi Chen,Weiping Zang and Jianguo Tian, “Optical limiting in one-dimensional photonic bandgap material with a bulk nonlinear defect,” J. Opt. 13, 015202 (2011).

13. Zhibo Liu, Li Li, Yanfei Xu, Jiajie Liang, Xin Zhao, Shuqi Chen, Yongsheng Chen, and Jianguo Tian, “Direct patterning on reduced graphene oxide nanosheets using femtosecond laser pulses,” J. Opt. 13, 085601 (2011).


2009年


12. Shuqi Chen, Weiping Zang, Axel Schülzgen, Xin Liu, Jianguo Tian, Jerome V. Moloney, and Nasser Peyghambarian, “Modeling of Z-scan characteristics for one-dimensional nonlinear photonic bandgap materials,” Opt. Lett. 34, 3665 (2009).


2008年


11. Shuqi Chen, Weiping Zang, Axel Schülzgen, Jinjie Liu, Lin Han, Yong Zeng, Jianguo Tian, Feng Song, Jerome V. Moloney, and Nasser Peyghambarian, “Implicit high-order unconditionally stable complex envelope algorithm for solving the time-dependent Maxwell's equations,” Opt. Lett. 33, 2755 (2008).

10. Shuqi Chen, Lin Han, Axel Schülzgen, Hongbo Li, Li Li, Jerome V. Moloney, and N. Peyghambarian, “Local electric field enhancement and polarization effects in a surface-enhanced Raman scattering fiber sensor with chessboard nanostructure,” Optics Express 16, 13016 (2008).

9. Lin Han, Feng Song, Shuqi Chen, Changguang Zou, Xiaochen Yu, Jianguo Tian, Jun Xu, Xiaodong Xu, and Guangjun Zhao, “Intense upconversion and infrared emissions in Er3+-Yb3+ codoped Lu2SiO5 and (Lu0.5Gd0.5)2SiO5 crystals,” Appl. Phys. Lett. 93, 011110 (2008).


2007年


8. Shuqi Chen, Weiping Zang, Zhibo Liu, Wenyuan Zhou, Yongfa Kong, and Jianguo Tian, “Method for measurements of second-order nonlinear optical coefficient based on Z-scan,” Opt. Commun. 274, 213 (2007).

7. Bing Zhang, Zhibo Liu, Shuqi Chen, Wenyuan Zhou, Weiping Zang, Jianguo Tian, Daibing Luo, and Zhiang Zhu, “Reverse saturable absorption of porphyrin-like complexes,” Acta. Phys. Sin. 56, 5252 (2007). (In Chinese)


2006年及以前


6. Shuqi Chen, Zhibo Liu, Weiping Zang, Jianguo Tian, Wenyuan Zhou, and Chunping Zhang, “Study on Z-scan characteristics for large optical nonlinear phase shift,” Acta. Phys. Sin. 55, 1211 (2006). (In Chinese)

5. Zhibo Liu, Yizhou Zhu, Yan Zhu, Shuqi Chen, Jianyu Zheng, and Jianguo Tian, “Nonlinear Absorption and Nonlinear Refraction of Self-Assembled Porphyrins,” J. Phys. Chem. B 110, 15140 (2006).

4. Zhibo Liu, Jianguo Tian, Jianyu Zheng, Zhiyu Li, Shuqi Chen, and Yan Zhu, “Active tuning of nonlinear absorption in a supramolecular zinc diphenylporphyrin-pyridine system,” Optics Express 14, 2770 (2006).

3. Shuqi Chen, Zhibo Liu, Weiping Zang, Jianguo Tian, Wenyuan Zhou, Feng Song, and Chunping Zhang, “Study on Z-scan characteristics for a large nonlinear phase shift,” J. Opt. Soc. Am. B 22, 1191 (2005).

2. Zhibo Liu, Jianguo Tian, Wenyuan Zhou, Shuqi Chen, Weiping Zang, Feng Song, and Jingjun Xu, “Characteristics of co-existence of third-order and transient thermally induced optical nonlinearities in nanosecond regime,” Opt. Commun. 245, 377 (2005).

1. Shuqi Chen, Zhibo Liu, Jianguo Tian, Wenyuan Zhou, Weiping Zang, Feng Song, and Chunping Zhang, “The influence of pulse width on transient thermally induced optical nonlinearitie s in a Kerr nonlinear medium,” Acta. Phys. Sin. 53, 3577 (2004). (In Chinese)

学术交流

学术兼职:


 2018/07       

《光学学报》,第七届编委(2019年-2021年)   


 2018/05 

 Scientific Reports, Editorial Board (Electronics, Photonics and Device Physics)


 2018/05 

 光学学报, Topical Editor (光场调控方向

 

 2018/03      

 天津市优秀创新创业导师人才库


 2017/07

 中国激光杂志社青年编辑委员会常务委员


 2017/01

 American Journal of Optics and Photonics, Editorial Board

荣誉奖励

个人奖励:


2018/03      

天津市优秀创新创业导师人才库  

2017/07

第十四届“挑战杯”天津市大学生课外学术科技作品竞赛优秀指导教师

2016/9

入选天津市“131”创新型人才培养工程第二层次人选

2014/11

入选南开大学百名青年学科带头人培养计划

2013/10

入选教育部新世纪优秀人才支持计划

2013/06

第十二届“挑战杯”天津市大学生课外学术科技作品竞赛优秀指导教师

2012/10

荣获南开大学捷成奖教金


学生奖励:


2015/6  

南开大学国家大学生创新性实验计划特等奖

2013/10

全国第十三届“挑战杯”二等奖

2013/9  

天津市优秀本科毕业论文  

2013/6  

天津市第十二届“挑战杯”特等奖

2013/6  

南开大学国家大学生创新性实验计划特等奖


学术成果

学位: 博士

毕业院校:

邮件: schen@nankai.edu.cn

办公地点: 物理学院 5教315室/泰达应用物理研究院 7区423室

电话: 010-62325064

出生年月:

10 访问

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