Identyfikatory
DOI
Warianty tytułu
Języki publikacji
Abstrakty
The negative refractions are discussed in detail to demonstrate two different two-dimensional photonic crystal structures that undergo negative refractions associated with the backward-wave and forward-wave phenomenon, respectively. The presentation of the left-handed property of effective negative index photonic crystal is followed by a discussion of a backward flowing phase and causality. The forward-wave negative refraction occurs in photonic crystals as a result of anisotropy. This paper is based on the theoretical analysis and is illustrated with the results of finite element method simulations.
Czasopismo
Rocznik
Tom
Strony
17--27
Opis fizyczny
Bibliogr. 25 poz., rys., wyk., tab.
Twórcy
autor
- College of Physical Electronics, University of Electronic Science and Technology of China, Sichuan Province 610054, China
autor
- College of Physical Electronics, University of Electronic Science and Technology of China, Sichuan Province 610054, China
autor
- College of Instrument Science and Opto-electronic Engineering, Hefei University of Technology, Hefei 230009, China
Bibliografia
- [1] TAYA S.A., EL-AGEZ T.M., KULLAB H.M., ABADLA M.M., SHABAT M.M., Theoretical study of slab waveguide optical sensor with left-handed material as a core layer, Optica Applicata 42(1), 2012, pp. 193–205.
- [2] LEI KANG, QIAN ZHAO, HONGJIE ZHAO, JI ZHOU, Magnetically tunable negative permeability metamaterial composed by split ring resonators and ferrite rods, Optics Express 16(12), 2008, pp. 8825–8834.
- [3] VALANJU P.M., WALSER R.M., VALANJU A.P., Wave refraction in negative-index media: always positive and very inhomogenous, Physical Review Letters 88(18), 2002, article 187401.
- [4] BOARDMAN A.D., EGAN P., VELASCO L., KING N., Control of planar nonlinear guided waves and spatial solitons with a left-handed medium, Journal of Optics A: Pure and Applied Optics 7(2), 2005, pp. S57–S67.
- [5] BOARDMAN A.D., KING N., VELASCO L., Negative refraction in perspective, Electromagnetics 25(5), 2005, pp. 365–389.
- [6] PICHARD H., RICHOUX O., GROBY J.-P., Experimental demonstrations in audible frequency range of band gap tunability and negative refraction in two-dimensional sonic crystal, The Journal of the Acoustical Society of America 132(4), 2012, pp. 2816–2822.
- [7] YANGBO XIE, POPA B.-I., ZIGONEANU L., CUMMER S.A., Measurement of a broadband negative index with space-coiling acoustic metamaterials, Physical Review Letters 110(17), 2013, article 175501.
- [8] PENG DONG, HONG WEI YANG, Guided modes in slab waveguides with both double-negative and single-negative materials, Optica Applicata 40(4) , 2010, pp. 873–882.
- [9] DEMS M., NAKWASKI W., The modelling of high-contrast photonic crystal slabs using the novel extension of the effective index method, Optica Applicata 36(1) , 2006, pp. 51–56.
- [10] AMOOGHORBAN E., ASGER MORTENSEN N., WUBS M., Quantum optical effective-medium theory for loss-compensated metamaterials, Physical Review Letters 110(15), 2013, article 153602.
- [11] VESELAGO V.G., The electrodynamics of substances with simultaneously negative values of ε and μ, Soviet Physics Uspekhi 10(4) 1968, pp. 509–514.
- [12] ZHENG-GAO DONG, SHUANG-YING LEI, MING-XIANG XU, HUI LIU, TAO LI, FU-MING WANG, SHI-NING ZHU, Negative index of refraction in metallic metamaterial comprising split-ring resonators, Physical Review E 77(5), 2008, article 056609.
- [13] KANG L., LIPPENS D., Mie resonance based left-handed metamaterial in the visible frequency range, Physical Review B 83(19), 2011, article 195125.
- [14] VON RHEIN A., PERGANDE D., GREULICH-WEBER S., WEHRSPOHN R.B., Experimental verification of apparent negative refraction in low-epsilon material in the microwave regime, Journal of Applied Physics 101(8), 2007, article 086103.
- [15] KALITEEVSKI M.A., BRAND S., GARVIE-COOK J., ABRAM R.A., CHAMBERLAIN J.M., Terahertz filter based on refractive properties of metallic photonic crystal, Optics Express 16(10), 2008, pp. 7330–7335.
- [16] MOUSSA R., FOTEINOPOULOU S., LEI ZHANG, TUTTLE G., GUVEN K., OZBAY E., SOUKOULIS C.M., Negative refraction and superlens bahavior in a two-demensional photonic crystal, Physical Review B 71(8), 2005, article 085106.
- [17] LALOUAT L., CLUZEL B., SALOMON L., DUMAS C., SEASSAL C., LOUVION N., CALLARD S., DE FORNEL F., Real space observation of two-dimensional Bloch wave interferences in a negative index photonic crystal cavity, Physical Review B 78(23), 2008, article 235304.
- [18] PARIMI P.V., LU W.T., VODO P., SOKOLOFF J., DEROV J.S., SRIDHAR S., Negative refraction and left--handed electromagnetism in microwave photonic crystals, Physical Review Letters 92(12), 2004, article 127401.
- [19] DECOOPMAN T., TAYEB G., ENOCH S., MAYSTRE D., GRALAK B., Photonic crystal lens: from negative refraction and negative index to negative permittivity and permeability, Physical Review Letters 97(7), 2006, article 073905.
- [20] KEN-MING LIN, GUO G.Y., Uncoupled modes and all-angle negative refraction in walled honeycomb photonic crystals, Journal of the Optical Society of America B 25(12), 2008, pp. C75–C81.
- [21] BELHADJ W., GAMRA D., ABDELMALEK F., HAXHA S., BOUCHRIHA H., Design of two-dimensional photonic crystal structure based in all-angle negative refractive effect for application in focusing systems, IET Optoelectronics 1(2), 2007, pp. 91–95.
- [22] ZHAOLIN LU, PRATHER D.W., Calculation of effective permittivity, permeability, and surface impedance of negative-refraction photonic crystals, Optics Express 15(13), 2007, pp. 8340–8354.
- [23] XIANGDONG ZHANG, Image resolution depending on slab thickness and object distance in a two-dimensional photonic-crystal-based superlens, Physical Review B 70(19), 2004, article 195110.
- [24] CHIYAN LUO, JOHNSON S.G., JOANNOPOULOS J.D., PENDRY J.B., All-angle negative refraction without negative effective index, Physical Review B 65(20), 2002, article 201104(R).
- [25] CHIYAN LUO, JOHNSON S.G., JOANNOPOULOS J.D., PENDRY J.B., Subwavelength imaging in photonic crystals, Physical Review B 68(4), 2003, article 045115
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-18b76cf8-2fbd-4b0c-aa24-f461d4e9e341