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材料工程  2008, Vol. 0 Issue (10): 118-121,125    
  "2008第七届中国国际纳米科技(武汉)研讨会"论文专辑 本期目录 | 过刊浏览 | 高级检索 |
周期渐变型准金刚石结构光子晶体的双光子聚合纳米加工技术
董贤子1,2, 赵震声1, 段宣明1
1. 中国科学院理化技术研究所有机纳米光子学实验室光化学转换与功能材料重点实验室, 北京, 100190;
2. 中国科学院研究生院, 北京, 100190
Gradient Quasidiamond Lattice Photonic Crystal Fabricated by Two-photon Polymerization Nanofabrication
DONG Xian-zi1,2, ZHAO Zhen-sheng1, DUAN Xuan-ming1
1. Laboratory of Organic NanoPhotonics and Key Laboratory of Photochemical Conversion & Optoelectronic Materials, Technical Institute of Physics and Chemistry, Chinese Academy of Sciences, Beijing 100190, China;
2. Graduate School of Chinese Academy of Sciences, Beijing 100190, China
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摘要 利用双光子聚合加工技术在低折射率材料中制备了具有宽带隙的光子晶体结构,通过递推方式获得晶格常数的最佳变化条件。通过透射及反射谱测量及时域有限差分方法证实了周期渐变的准金刚石结构的带隙展宽现象,该结果表明三维光子晶体带隙展宽可由不同晶格常数的结构叠加形成。
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董贤子
赵震声
段宣明
关键词 光子晶体双光子聚合准金刚石结构光子带隙    
Abstract:Wide Photonic Band Gaps(PBG) with low refractive index materials were fabricated using two-photon nanofabrication technique.The fittest lattice change condition was deduced by a simple method.The PBG of the gradient quasi-diamond lattices was experimentally confirmed by reflection and transmission measurements and simulation of Finite Difference Time Domain(FDTD) calculations.The results indicate that a three dimensional photonic crystals with gradient lattices could effectively expand the width of the PBG.
Key wordsphotonic crystal    twophoton polymerization    quasidiamond lattice    PBG
收稿日期: 2008-06-25      出版日期: 2008-10-20
中图分类号:  TN203  
基金资助:国家自然科学基金项目(No.50773091)
作者简介: 董贤子(1977- ), 女, 助理研究员, 博士研究生, 主要从事激光微纳加工, 光子晶体微器件研究, 联系地址: 北京中关村北一条2号, 北京市2711信箱54分箱(100190).E-mail: dongxianzi@mail.ipc.ac.cn
引用本文:   
董贤子, 赵震声, 段宣明. 周期渐变型准金刚石结构光子晶体的双光子聚合纳米加工技术[J]. 材料工程, 2008, 0(10): 118-121,125.
DONG Xian-zi, ZHAO Zhen-sheng, DUAN Xuan-ming. Gradient Quasidiamond Lattice Photonic Crystal Fabricated by Two-photon Polymerization Nanofabrication. Journal of Materials Engineering, 2008, 0(10): 118-121,125.
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http://jme.biam.ac.cn/CN/      或      http://jme.biam.ac.cn/CN/Y2008/V0/I10/118
[1] YABLONOVlTCH E.Inhibited spontaneous emission in solidstate physics and electronics[J].Physical Review Letters,1987,58(20):2059-2062.
[2] JOHN S.Strong localization of photons in certain disordered dielectric superlattices[J].Physical Review Letters,1987,58(23):2486-2489.
[3] SUN H B,MATSUO S.MISAWA H.Three-dimensional photonic crystal structures achieved with two-photon-absorption photopolymerization of resin[J].Applied Physics Letters,1999,74(6):786-788.
[4] KANEKO K,SUN H B,DUAN X M.et al.Submicron diamond-lattice photonie crystals produced by two-photon laser nanofabrication[J].Applied Physics Letters.2003,83(11):2091-2093.
[5] SEET K K,MIZEIKIS V,JUODKAZIS S,et al.Three-dimensional horizontal drcular spiral photonic crystals with stop gaps below 1 μm[J].Applied Physics Letters,2006,88(22):21101(1-3).
[6] KAWATA S,SUN H B,TANAKA T,et al.Finer features for functional microdevices-Micromachines can be created with higher resolution using two-photon absorption[J].Nature,2001,412(6848):697-698.
[7] TAKADA K,SUN H B,KAWATA S.Improved spatial resolution and surface roughness in photopolymerization-based laser nanowriting[J].Applied Physics Letters,2005,86(7):071122(1-3).
[8] DONG X Z,ZHAO Z S,DUAN X M.Improving spatial reaolution and reducing aspect ratio in muhiphoton polymerization nano fabrication[J].Applied Physics Letters,2008,92(9):091113(1-3).
[9] HASKE W,CHEN V W,HALESJ M.et al.65nm feature sizes using visible wavelength 3-D muhiphoton lithography[J].Optics Express,2007,15(6):3426-3436.
[10] DUAN X M,SUN H B,KANEKO K,et al.Two-photon polyerization of met al ions doped acrylate monomers and oligomers for three-dimensional structure fabrication[J].Thin Solid Films,2004,453:518-521.
[11] SUN Z B,DONG X Z,NAKANISHI S,et al.Log-pile photonic crystal of CdS-polymer nanocomposites fabricated by combination of two-photon polymerization and in situ synthesis[J].Applied Physics a-Materials Science & Processing,2007,86(4):427-431.
[12] SUN Z B,DONG X Z,CHEN W Q,et al.Multicolor polymer nanocomposites:in situ synthesis and fabrication of 3D microstructures[J].Advanced Materials,2008,20(5):914-919.
[13] JEON S,NAM Y S,SHIR D J L,et al.Three dimensional nanoporous density graded materials formed by optical exposures through conformable phase masks[J].Applied Physics Letters,2006,89(25):253101(1-3).
[14] PARK J H.CHOlW S,KOO H Y,et al.Doped colloidal photonic crystal structure with refractive index chirping to the[111] crystallographic axis[J].Langmuir,2006,22(1):94-100.
[15] LI J,XUE L J,WANG Z,et al.Colloidal photonic crystals with a graded lattice-constant distribution[J].Colloid and Polymer Science,2007,285(9):1037-1041.
[16] DONG X Z,YA Q,SHENG X Z,et al.Photonic bandgap of gradient quasidiamond lattice photonic crystal[J].Applied Physics Letters,2008,92(23):231103(1-3).
[17] CHAN C T,HO K M.SOUKOULIS C M.Photonic band gaps in experimentally realizable periodic dielectric structures[J].Europhys Lett,1991,16(6):563-568.
[18] 董贤子,段宣明.双光子三维微结构快速制备技术[J].光学精密工程,2007,15(4):441-446.
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