[1]杨毅彪,王云才,王拴锋,等.二维介质柱型graphite格子光子晶体禁带特性[J].深圳大学学报理工版,2010,27(2):157-161.
 YANG Yi-biao,WANG Yun-cai,WANG Shuan-feng,et al.The bandgap characteristics of two dimensional graphite lattice photonic crystals with dielectric rods[J].Journal of Shenzhen University Science and Engineering,2010,27(2):157-161.
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二维介质柱型graphite格子光子晶体禁带特性()
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《深圳大学学报理工版》[ISSN:1000-2618/CN:44-1401/N]

卷:
第27卷
期数:
2010年2期
页码:
157-161
栏目:
光电与信息工程
出版日期:
2010-04-30

文章信息/Info

Title:
The bandgap characteristics of two dimensional graphite lattice photonic crystals with dielectric rods
文章编号:
1000-2618(2010)02-0157-05
作者:
杨毅彪1王云才1王拴锋1王伟军1梁伟2
1)太原理工大学理学院,太原 030024
2)太原理工大学材料科学与工程学院,太原 030024
Author(s):
YANG Yi-biao1WANG Yun-cai1WANG Shuan-feng1WANG Wei-jun1and LIANG Wei2
1)College of Science,Taiyuan University of Technology,Taiyuan 030024,P.R.China
2)College of Materials Science and Engineering,Taiyuan University of Technology,Taiyuan 030024,P.R.China
关键词:
光子晶体光学禁带特性平面波展开法graphite格子
Keywords:
photonic crystalsopticsbandgap characteristicsplane wave expansion methodgraphite lattice
分类号:
O 472.3;O 481.1
文献标志码:
A
摘要:
采用平面波展开法模拟由GaAs、Si 和Ge介质柱构造的graphite 格子二维光子晶体的禁带结构.数值计算发现,无论由圆形、正六边形或正方形介质柱构造的graphite格子,出现完全光子禁带时对应的填充比f可变化范围都非常大.Graphite格子光子晶体在介质折射率最低为2.2时出现完全光子禁带.当介质材料折射率n在3.4~3.9范围变化时,最大禁带宽度Δ可保持在0.050[ωa/(2πc)]以上,最大完全禁带宽度与中心频率的比值稳定在15%.
Abstract:
The photonic bandgaps of two dimensional photonic crystals with graphite lattice were simulated using the plane wave expansion method. Our simulation results show that the complete bandgaps appear when filling fraction f changes in a wide range and when the dielectric rods are circular,hexagonal or square. The complete photonic band gap is observed when the refractive index is more than 2.2. The obtained maximum complete photonic band gap is over 0.050[ωa/(2πc)] and the complete band gap width to midgap frequency is about 15% when the refractive index of dielectric materials change within the range 3.4~3.9.

参考文献/References:

[1]Yablonovitch E.固体物理和电子学中的抑制自发辐射[J].物理评论快报,1987,58(20):2059-2062.(英文版)
[2]John S.在无序介质超晶格中的强烈光子局域现象[J].物理评论快报,1987,58(23):2486-2489.(英文版)
[3]Francardi M,Gerardino A,Balet L,等.在通信波段基于光子晶体纳米腔的单光子源发光二极管[J].微电子工程,2008,85(5-6):1162-1165.(英文版)
[4]Djavid M,Ghaffari A,Monifi F,等.双周期结构的光子晶体窄带滤波器[J].应用科学学报,2008,8(10):1891-1897.(英文版)
[5]郭媛,阮双琛,于永芹,等.光子晶体光纤产生超连续谱的相干性研究[J].深圳大学学报理工版,2007,24(2) :149-153.(英文版)
[6]Notomi M,Tanabe T,Kuramochi E,等.利用光子晶体纳米腔在硅芯片上实现全光开关[J].应用物理快报,2005,87(15):151112.(英文版)
[7]Rechtsman M C,Stillinger F H,Torquato S.针对自组装的优化相互作用:在蜂窝型晶格的应用[J].物理评论快报,2005,95:228301.(英文版)
[8]Knight J C.光子晶体光纤[J].自然,2003,424(6950):847-851.(英文版)
[9]Russell P.光子晶体光纤[J].科学,2003,299(5605):358-362.(英文版)
[10]Vecchi G,Raineri F,Sagnes I,等.由镀金硅片光子晶体实现近1.55微米的激光表面发射[J].电子学快报,2007,43(6).(英文版)
[11]Han-Youl Ryu,Jeong-Ki Hwang,Yong-Hee Lee.大小不均匀对二维光子晶体禁带的影响[J].物理评论B,1999,59(8) :5463-5469.(英文版)
[12]Gaji R,Meisels R,Kuchar F,等.Kagomé和honeycomb晶格光子晶体中全角域的左手负折射[J].物理评论B,2006,73 :165310.(英文版)
[13]Qiu Gaoxin,Vynck Kevin,Cassagne David,等.二维和三维混合硅基反蛋白石光子晶体宽带单模波导[J].光学快讯,2007,15(6):3502-3506.(英文版)
[14]Gruning U,Lehmann V,Ottow S,等.完全光子带隙中心在5 μm的二维宏孔硅[J].应用物理快报,1996,68(6):747-749.(英文版)
[15]赵明明,吕燕伍,余家新,等.旋转对二维正方晶格介质柱内空结构光子晶体禁带的影响[J].物理学报,2008,57(2):1061-1065.



[1]Yablonovitch E.Inhibited spontaneous emission in solid-state physics and electronics[J].Phys Rev Lett,1987,58(20):2059-2062.
[2]John S.Strong localization of photons in certain disordered dielectric superlattices[J].Phys Rev Lett,1987,58(23):2486-2489.
[3]Francardi M,Gerardino A,Balet L,et al.Towards a LED based on a photonic crystal nanocavity for single photon sources at telecom wavelength[J].Microelectronic Engineering,2008,85(5-6):1162-1165.
[4]Djavid M,Ghaffari A,Monifi F,et al.Photonic crystal narrow band filters using biperiodic structures[J].Journal of Applied Sciences,2008,8(10):1891-1897.
[5]GUO Yuan,RUAN Shuang-chen,YU Yong-qin,et al.Analysis on the coherence properties of supercontinuum spectra generated in a photonic crystal fiber[J].Journal of Shenzhen University Science and Engineering,2007,24(2) :149-153.
[6]Notomi M,Tanabe T,Kuramochi E,et al.All-optical switches on a silicon chip realized using photonic crystal nanocavities[J].Appl Phys Lett,2005,87(15):151112.
[7]Rechtsman M C,Stillinger F H,Torquato S.Optimized interactions for targeted self-assembly:application to a honeycomb lattice[J].Phys Rev Lett,2005,95:228301.
[8]Knight J C.Photonic crystal fibres[J].Nature,2003,424(6950):847-851.
[9]Russell P.Photonic crystal fibers[J].Science,2003,299(5605):358-362.
[10]Vecchi G,Raineri F,Sagnes I,et al.Photonic-crystal surface-emitting laser near 1.55 μm on gold-coated silicon wafer[J].Electronics Letters,2007,43(6).
[11]Han-Youl Ryu,Jeong-Ki Hwang,Yong-Hee Lee.Effect of size nonuniformities on the band gap of two-dimensional photonic crystals[J].Phys Rev B,1999,59(8) :5463-5469.
[12]Gaji R,Meisels R,Kuchar F,et al.All-angle left-handed negative refraction in Kagomé and honeycomb lattice photonic crystals[J].Phys Rev B,2006,73 :165310.
[13]Qiu Gaoxin,Vynck Kevin,Cassagne David,et al.Broadband single-mode waveguiding in two-and three-dimensional hybrid photonic crystals based on silicon inverse opals[J].Optics Express,2007,15(6):3502-3506.
[14]Gruning U,Lehmann V,Ottow S,et al.Macroporous silicon with a complete two-dimensional photonic band gap centered at 5 μm[J].Appl Phys Lett,1996,68(6):747-749.
[15]ZHAO Ming-ming,LU Yan-wu,YU Jia-xin,et al.Effect of rotation on photonic band gap of two-dimensional square lattice photonic crystal with hollow rod[J].Acta Physica Sinica, 2008, 57(2): 1061-1065.(in chinese)

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备注/Memo

备注/Memo:
收稿日期:2010-03-17
基金项目:山西省国际科技合作基金资助项目(2007081019)
作者简介:杨毅彪(1967-),男(汉族),山西省太原市人,太原理工大学副教授、博士.E-mail:yanyibiao_tyut@sohu.com
通讯作者:王云才(1965-),男(汉族),太原理工大学教授、博士生导师.E-mail:wangyc@tyut.edu.cn
更新日期/Last Update: 2010-05-08