Negative Refraction and Imaging Using 12-fold-Symmetry Quasicrystals

Zhao, Feng; Zhang, Xiangdong; Wang, Yiquan; Li, Zhiyuan; Cheng, Bingying; Zhang, Daozhong

doi:10.1103/physrevlett.94.247402

Cited by 111 publications

(74 citation statements)

References 39 publications

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“…Nonetheless, PQC can still have relatively sharp diffraction patterns due to longrange order. Such patterns confirm the existence of wave scattering and interference, providing similar functionalities as periodic counterparts, such as photonic band gaps [12][13][14][15], negative refraction [16], lasing [17][18][19], and nonlinear light propagations [20][21][22]. We will show theoretically and experimentally that some two-dimensional photonic quasicrystalline approximants can possess conical dispersion at k ¼ 0, and their finite-sized counterparts can behave like a zero-refractive-index medium as evidenced by different experimental measurements.…”

supporting

confidence: 52%

“…Photonic quasicrystal (PQC) is constructed by building blocks positioned on well-designed patterns but lacks translational symmetry [12][13][14][15][16][17][18][19][20][21][22][23]. Nonetheless, PQC can still have relatively sharp diffraction patterns due to longrange order.…”

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confidence: 99%

“…Even amorphous photonic crystals support band gaps [32], but disorder as a precursor to level repulsion can eliminate the conical dispersion (Supplemental Material [25], Appendix G). This is unlike using quasicrystals to realize the effective negative index in which the negative index will persist independent of the detailed arrangement of the "atoms" as long as the filling ratio is correct [16]. In addition, one can also extend the concepts to optical frequencies as the PQC is constructed by all-dielectric and low-loss rods.…”

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Conical Dispersion and Effective Zero Refractive Index in Photonic Quasicrystals

et al. 2015

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It is recognized that for a certain class of periodic photonic crystals, conical dispersion can be related to a zero-refractive index. It is not obvious whether such a notion can be extended to a noncrystalline system. We show that certain photonic quasicrystalline approximants have conical dispersions at the zone center with a triply degenerate state at the Dirac frequency, which is the necessary condition to qualify as a zerorefractive-index medium. The states in the conical dispersions are extended and have a nearly constant phase. Experimental characterizations of finite-sized samples show evidence that the photonic quasicrystals do behave as a near zero-refractive-index material around the Dirac frequency. [10]. However, the connection between conical dispersions at k ¼ 0 and zero-refractive index were built upon periodicity. The conical dispersion was obtained by tuning the system parameters of "one-atom-per-unit-cell" photonic crystals with a well-defined photonic band structure. Whether a conical dispersion can exist in a nonperiodic system is still an interesting and open question. Furthermore, the claim that a system behaves like a zero-index medium implicitly assumes that an effective medium description could be applied. While not explicitly stated, many coherent-potential-approximation-type effective medium theories, employed to map a Dirac cone to zero index [11], assume that each scatter resides in the same environment. Although this assumption of periodicity is not needed in the ω → 0, k → 0 limit, it is not immediately obvious that such effective medium description can be applied to nonperiodic systems if we consider effective parameters at k → 0 but at a finite frequency such as a Dirac point. Can a nonperiodic system behave operationally as if it has zero-refractive index?Photonic quasicrystal (PQC) is constructed by building blocks positioned on well-designed patterns but lacks translational symmetry [12][13][14][15][16][17][18][19][20][21][22][23]. Nonetheless, PQC can still have relatively sharp diffraction patterns due to longrange order. Such patterns confirm the existence of wave scattering and interference, providing similar functionalities as periodic counterparts, such as photonic band gaps [12][13][14][15], negative refraction [16], lasing [17][18][19], and nonlinear light propagations [20][21][22]. We will show theoretically and experimentally that some two-dimensional photonic quasicrystalline approximants can possess conical dispersion at k ¼ 0, and their finite-sized counterparts can behave like a zero-refractive-index medium as evidenced by different experimental measurements.In this Letter, we show the existence of conical dispersions and extended states with zero-refractive-index characteristics in some PQCs, and experimentally characterize these states. The extended states are close to the Dirac frequency, and form two cones intersecting at a "Dirac point." The eigenmodes have almost constant field intensity at each quasicrystalline site, regardless of the size and the bounda...

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confidence: 52%

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confidence: 99%

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confidence: 99%

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Conical Dispersion and Effective Zero Refractive Index in Photonic Quasicrystals

et al. 2015

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“…The super-prism effect is another exciting property arising from the photonic crystals [19,32]. Extensive numerical [21,33,34] and experimental studies [35][36][37] provided a better understanding of negative refraction, focusing and sub-wavelength imaging in photonic crystal structures. Masaya Notomi showed that refraction-like behaviour could be expected to occur in photonic crystals that exhibit negative refraction for certain lattice parameters.…”

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confidence: 99%

Negative Refraction by Photonic Crystal

Srivastava¹,

Srivastava²,

Ojha³

2008

PIER B

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Abstract-Negative refraction has been the subject of considerable interest and it may provide the possibility of a variety of novel applications. It arises in metamaterials that have simultaneous negative permittivity ε and permeability µ, where in-homogeneities are much smaller than the wavelength of the incoming radiation. Recently it has been shown that photonic crystals (PCs) may also exhibit negative refraction although they have a periodically modulated positive permittivity ε and permeability µ. We have theoretically studied the negative refraction in one-dimensional (1D) photonic crystals (PCs) consisting dielectric ZnSe with air. By using transfer matrix method and block theorem we have studied the photonic band structure and group velocity and with the help of group velocity we have obtained the frequency bands of negative refraction. We found that negative refraction may occur near the low frequency edge of the second and fourth bandgaps. We have also studied the effective index of refraction and the transverse position shift through PC that can characterize negative refraction more explicitly.

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“…It has been demonstrated theoretically and experimentally that both left-handed metamaterials [4 -7] and photonic crystals [8][9][10][11][12][13][14][15] can achieve NR from microwave to near-infrared frequencies. Furthermore, all-angle NR (AANR) for lens imaging at microwave frequencies by metamaterials [16,17] and at optical frequencies by photonic crystals [18,19] has also been demonstrated recently, but the operating bandwidth is still limited in a narrower frequency range [16 -19], and the realization of broadband AANR at an optical frequency, especially in the visible region, is still a challenge.Generally speaking, a periodic structure is capable of producing NR for electromagnetic waves. For example, a simple dielectric waveguide array can bend light in the direction opposite to that observed in common media at a limited incident angle within a narrow frequency bandwidth [20,21].…”

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All-Angle Broadband Negative Refraction of Metal Waveguide Arrays in the Visible Range: Theoretical Analysis and Numerical Demonstration

et al. 2006

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In this Letter, we introduce a simple metal waveguide array for realizing all-angle wide frequency bandwidth negative refraction from the visible to infrared frequencies. Theoretical analysis from the rigorous coupled-wave theory reveals that the negative coupling constant resulting from the anomalous coupling of guided surface plasmon polariton modes contributes to the negative refraction. The analytical results are confirmed by finite-difference time-domain numerical simulations. Our result provides an alternative way to construct robust all-angle negative refractive materials operating in a wide range of frequency from the near-infrared to the visible range. DOI: 10.1103/PhysRevLett.97.073901 PACS numbers: 42.82.Et, 42.25.ÿp, 73.20.Mf, 78.67.ÿn The negative-refraction (NR) effect [1] has currently attracted considerable interest because it underlays the foundation of a variety of new potential applications [2] and the possibility of investigating extraordinary electromagnetic wave propagation phenomena [3]. It has been demonstrated theoretically and experimentally that both left-handed metamaterials [4 -7] and photonic crystals [8][9][10][11][12][13][14][15] can achieve NR from microwave to near-infrared frequencies. Furthermore, all-angle NR (AANR) for lens imaging at microwave frequencies by metamaterials [16,17] and at optical frequencies by photonic crystals [18,19] has also been demonstrated recently, but the operating bandwidth is still limited in a narrower frequency range [16 -19], and the realization of broadband AANR at an optical frequency, especially in the visible region, is still a challenge.Generally speaking, a periodic structure is capable of producing NR for electromagnetic waves. For example, a simple dielectric waveguide array can bend light in the direction opposite to that observed in common media at a limited incident angle within a narrow frequency bandwidth [20,21]. However, less attention was paid to its metallic counterparts, especially the nanoscale ones [22], until a very recent exploration that nanoscale metal waveguide arrays (MWGAs) show an interesting lens effect at a fixed optical wavelength [23]. In this Letter, we will reveal that nanoscale MWGAs can actually achieve AANR over a wide frequency bandwidth from visible to infrared ranges. We show the NR effect by the coupled-wave theory and further establish the effect by finite-difference timedomain (FDTD) numerical simulations. Further analysis on the conditions for AANR implies that MWGAs are suitable for visible wavelength operation in a wide bandwidth. We attribute the NR effect to coupling of propagating surface plasmon polaritons (SPPs) among the adjacent guides.Our work begins with the analysis of a simple discrete system containing two adjacent two-dimensional (2D) metal waveguides by a rigorous field analysis approach, where linear coupling of propagating SPPs in the guides is considered. The structure is schematically drawn in Fig. 1(a); h is the guide width and d is the thickness of the metal film. " 1 >0 and ...

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Negative Refraction and Imaging Using 12-fold-Symmetry Quasicrystals

Cited by 111 publications

References 39 publications

Conical Dispersion and Effective Zero Refractive Index in Photonic Quasicrystals

Conical Dispersion and Effective Zero Refractive Index in Photonic Quasicrystals

Negative Refraction by Photonic Crystal

All-Angle Broadband Negative Refraction of Metal Waveguide Arrays in the Visible Range: Theoretical Analysis and Numerical Demonstration

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