Zero phase delay in negative-refractive-index photonic crystal superlattices

Kocaman, Serdar; Aras, Mehmet; Hsieh, Pang‐Hsin; McMillan, James F.; Biris, Claudiu G.; Panoiu, Nicolae C.; Yu, Mingbin; Kwong, Dim‐Lee; Stein, A.; Wong, Chee Wei

doi:10.1038/nphoton.2011.129

Cited by 118 publications

(75 citation statements)

References 51 publications

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“…Around the double Dirac point frequency, we reveal that a slab of our acoustic system can be mapped onto an acoustic zero-index medium (ZIM) by using a standard retrieval method. ZIMs [23][24][25][26][27][28][29][30][31][32] have spectacular applications, such as beam self-collimation, energy squeezing, and tunneling. Here, we demonstrate with two examples the interesting wave transport behaviors in our systems.…”

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confidence: 99%

Double Dirac cones in phononic crystals

Mei

2014

Applied Physics Letters

116

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A double Dirac cone is realized at the center of the Brillouin zone of a two-dimensional phononic crystal (PC) consisting of a triangular array of core-shell-structure cylinders in water. The double Dirac cone is induced by the accidental degeneracy of two double-degenerate Bloch states. Using a perturbation method, we demonstrate that the double Dirac cone is composed of two identical and overlapping Dirac cones whose linear slopes can also be accurately predicted from the method. Because the double Dirac cone occurs at a relatively low frequency, a slab of the PC can be mapped onto a slab of zero refractive index material by using a standard retrieval method. Total transmission without phase change and energy tunneling at the double Dirac point frequency are unambiguously demonstrated by two examples. Potential applications can be expected in diverse fields such as acoustic wave manipulations and energy flow control.

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confidence: 99%

Double Dirac cones in phononic crystals

Mei

2014

Applied Physics Letters

116

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“…To overcome these drawbacks, researchers have to introduce metamaterials into the PCs to obtained tunable PBGs [14] and zero-n PBGs [15]. Obviously, the zero-refractive indices can be obtained by metamaterials [16,17]. Metamaterials are firstly proposed by Veselago in 1967 [18], and can exhibit a negative index of refraction in some frequency ranges.…”

Section: Introductionmentioning

confidence: 99%

Enhanced the Complete Photonic Band Gaps for Three-Dimensional Photonic Crystals Consisting of Epsilon-Negative Materials in Pyrochlore Arrangement

Zhang¹,

Liu²,

Zhao³

2014

PIER B

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Abstract-In this paper, the properties of photonic band gaps (PBGs) for three-dimensional (3D) photonic crystals (PCs) composed of isotropic positive-index materials and epsilon-negative materials with pyrochlore lattices are theoretically investigated by a modified plane wave expansion method. The eigenvalue equations of calculating the band structures for such 3D PCs in the first irreducible Brillouin zone (spheres with the isotropic positive-index materials inserted in the epsilon-negative materials background) are theoretically deduced. Numerical simulations show that the PBG and a flatbands region can be achieved. It is also found that larger PBG can be obtained in such PCs structure than the conventional lattices, such as diamond, face-centered-cubic, body-centered-cubic and simple-cubic lattices. The influences of the relative dielectric constant of spheres, filling factor, electronic plasma frequency, dielectric constant of epsilon-negative materials and damping factor on the properties of PBG for such 3D PCs are studied in detail, respectively, and some corresponding physical explanations are also given. The calculated results also show that the PBG can be manipulated by the parameters mentioned above except for the damping factor. Introducing the epsilon-negative materials into 3D dielectric PCs can obtain the complete and larger PBG as such 3D PCs with pyrochlore lattices, and also provides a way to design the potential devices.

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“…Specifically, at this frequency the Bragg condition, k = ( n ω/c) = mπ, is satisfied for m = 0, irrespective of the period  of the superlattice; here, k and  are the wave vector and frequency, respectively, and n is the averaged refractive index. Because of this property this photonic bandgap is called zero-n , or zero-order, bandgap [30,34]. Near-zero index materials have a series of exciting potential applications, such as diffraction-free beam propagation over thousands of wavelengths via beam self-collimation [34], extremely convergent lenses and control of spontaneous emission [35], strong field enhancement in thin-film layered structures [37], and cloaking devices [40].…”

Section: Introductionmentioning

confidence: 99%