Please wait a minute...
Chinese Physics, 2006, Vol. 15(3): 552-555    DOI: 10.1088/1009-1963/15/3/018
CLASSICAL AREAS OF PHENOMENOLOGY Prev   Next  

Near-field imaging of a square-lattice metallic photonic-crystal slab at the second band

Feng Shuai (冯帅), Feng Zhi-Fang (冯志芳), Ren Kun (任坤), Ren Cheng (任承), Li Zhi-Yuan (李志远), Cheng Bing-Ying (程丙英), Zhang Dao-Zhong (张道中)
Institute of Physics, Chinese Academy of Sciences,Beijing National Laboratory for Condensed Matter Physics, Beijing 100080, China
Abstract  Imaging properties of a two-dimensional photonic crystal slab lens are investigated through the finite-difference time-domain method. In this paper, we consider the photonic crystal slab consisting of a square lattice of square metallic rods immersed in a dielectric background. Through the analysis of the equifrequency-surface contours and the field patterns of a point source placed in the vicinity of the photonic crystal slab, we find that a good-quality image can form at the frequencies in the second TM-polarized photonic band. Comparing the images formed at different frequencies, we can clearly see that an excellent-quality image is formed by the mechanisms of simultaneous action of the self-collimation effect and the negative-refraction effect.
Keywords:  negative refraction      photonic crystal  
Received:  10 October 2005      Revised:  27 December 2005      Accepted manuscript online: 
PACS:  42.70.Qs (Photonic bandgap materials)  
  42.30.-d (Imaging and optical processing)  
Fund: Project supported by the National Key Basic Research Special Foundation of China (Grant Nos 2004CB719804 and 2001CB610402), the National Natural Science Foundation of China (Grant No 10404036) and National Center for Nanoscience and Technology,China (Grant No 2003CB7169) also the support from the supercomputing Center, CNIC, CAS.

Cite this article: 

Feng Shuai (冯帅), Feng Zhi-Fang (冯志芳), Ren Kun (任坤), Ren Cheng (任承), Li Zhi-Yuan (李志远), Cheng Bing-Ying (程丙英), Zhang Dao-Zhong (张道中) Near-field imaging of a square-lattice metallic photonic-crystal slab at the second band 2006 Chinese Physics 15 552

[1] Nonreciprocal wide-angle bidirectional absorber based on one-dimensional magnetized gyromagnetic photonic crystals
You-Ming Liu(刘又铭), Yuan-Kun Shi(史源坤), Ban-Fei Wan(万宝飞), Dan Zhang(张丹), and Hai-Feng Zhang(章海锋). Chin. Phys. B, 2023, 32(4): 044203.
[2] Nonreciprocal negative refraction in a dense hot atomic medium
Hai Yi(易海), Hongjun Zhang(张红军), and Hui Sun(孙辉). Chin. Phys. B, 2023, 32(4): 044202.
[3] A 3-5 μm broadband YBCO high-temperature superconducting photonic crystal
Gang Liu(刘刚), Yuanhang Li(李远航), Baonan Jia(贾宝楠), Yongpan Gao(高永潘), Lihong Han(韩利红), Pengfei Lu(芦鹏飞), and Haizhi Song(宋海智). Chin. Phys. B, 2023, 32(3): 034213.
[4] Multi-band polarization switch based on magnetic fluid filled dual-core photonic crystal fiber
Lianzhen Zhang(张连震), Xuedian Zhang(张学典), Xiantong Yu(俞宪同), Xuejing Liu(刘学静), Jun Zhou(周军), Min Chang(常敏), Na Yang(杨娜), and Jia Du(杜嘉). Chin. Phys. B, 2023, 32(2): 024205.
[5] Method of measuring one-dimensional photonic crystal period-structure-film thickness based on Bloch surface wave enhanced Goos-Hänchen shift
Yao-Pu Lang(郎垚璞), Qing-Gang Liu(刘庆纲), Qi Wang(王奇), Xing-Lin Zhou(周兴林), and Guang-Yi Jia(贾光一). Chin. Phys. B, 2023, 32(1): 017802.
[6] Dual-channel tunable near-infrared absorption enhancement with graphene induced by coupled modes of topological interface states
Zeng-Ping Su(苏增平), Tong-Tong Wei(魏彤彤), and Yue-Ke Wang(王跃科). Chin. Phys. B, 2022, 31(8): 087804.
[7] High sensitivity dual core photonic crystal fiber sensor for simultaneous detection of two samples
Pibin Bing(邴丕彬), Guifang Wu(武桂芳), Qing Liu(刘庆), Zhongyang Li(李忠洋),Lian Tan(谭联), Hongtao Zhang(张红涛), and Jianquan Yao(姚建铨). Chin. Phys. B, 2022, 31(8): 084208.
[8] Design of a polarization splitter for an ultra-broadband dual-core photonic crystal fiber
Yongtao Li(李永涛), Jiesong Deng(邓洁松), Zhen Yang(阳圳), Hui Zou(邹辉), and Yuzhou Ma(马玉周). Chin. Phys. B, 2022, 31(5): 054215.
[9] Generation of mid-infrared supercontinuum by designing circular photonic crystal fiber
Ying Huang(黄颖), Hua Yang(杨华), and Yucheng Mao(毛雨澄). Chin. Phys. B, 2022, 31(5): 054211.
[10] High sensitivity plasmonic temperature sensor based on a side-polished photonic crystal fiber
Zhigang Gao(高治刚), Xili Jing(井西利), Yundong Liu(刘云东), Hailiang Chen(陈海良), and Shuguang Li(李曙光). Chin. Phys. B, 2022, 31(2): 024207.
[11] Topological photonic states in gyromagnetic photonic crystals: Physics, properties, and applications
Jianfeng Chen(陈剑锋) and Zhi-Yuan Li(李志远). Chin. Phys. B, 2022, 31(11): 114207.
[12] Bound states in the continuum in metal—dielectric photonic crystal with a birefringent defect
Hongzhen Tang(唐宏珍), Peng Hu(胡鹏), Da-Jian Cui(崔大健), Hong Xiang(向红), and Dezhuan Han(韩德专). Chin. Phys. B, 2022, 31(10): 104209.
[13] Momentum-space polarization fields in two-dimensional photonic-crystal slabs: Physics and applications
Wen-Zhe Liu(刘文哲), Lei Shi(石磊), Che-Ting Chan(陈子亭), and Jian Zi(资剑). Chin. Phys. B, 2022, 31(10): 104211.
[14] Mid-infrared supercontinuum and optical frequency comb generations in a multimode tellurite photonic crystal fiber
Xu Han(韩旭), Ying Han(韩颖), Chao Mei(梅超), Jing-Zhao Guan(管景昭), Yan Wang(王彦), Lin Gong(龚琳), Jin-Hui Yuan(苑金辉), and Chong-Xiu Yu(余重秀). Chin. Phys. B, 2021, 30(9): 094207.
[15] Dynamic modulation in graphene-integrated silicon photonic crystal nanocavity
Long-Pan Wang(汪陇盼), Cheng Ren(任承), De-Zhong Cao(曹德忠), Rui-Jun Lan(兰瑞君), and Feng Kang(康凤). Chin. Phys. B, 2021, 30(6): 064209.
No Suggested Reading articles found!