Conical Dispersion and Effective Zero Refractive Index in Photonic Quasicrystals

Dong, Jian‐Wen; Chang, Ming-Li; Huang, Xueqin; Hang, Zhi Hong; Zhong, Zhi-Chao; Chen, Wenjie; Huang, Zhanyun; Chan, Che Ting

doi:10.1103/physrevlett.114.163901

Cited by 84 publications

(55 citation statements)

References 30 publications

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“…Nevertheless there is still the potential for further cross-fertilization between different fields, going beyond the "artificial graphene" paradigm. A striking example of this is the recent discovery that a periodic lattice is not strictly necessary; conical intersections can also occur in quasiperiodic lattices [84].…”

Section: Discussionmentioning

confidence: 99%

Conical intersections for light and matter waves

Leykam

Desyatnikov

2016

Advances in Physics: X

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We review the design, theory, and applications of two dimensional periodic lattices hosting conical intersections in their energy-momentum spectrum. The best known example is the Dirac cone, where propagation is governed by an effective Dirac equation, with electron spin replaced by a "fermionic" half-integer pseudospin. However, in many systems such as metamaterials, modal symmetries result in the formation of higher order conical intersections with integer or "bosonic" pseudospin. The ability to engineer lattices with these qualitatively different singular dispersion relations opens up many applications, including superior slab lasers, generation of orbital angular momentum, zeroindex metamaterials, and quantum simulation of exotic phases of relativistic matter.

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Section: Discussionmentioning

confidence: 99%

Conical intersections for light and matter waves

Leykam

Desyatnikov

2016

Advances in Physics: X

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“…We see that both of the forbidden bands expand from below 2.5 GHz to above 2.7 GHz. At the upper bound of the forbidden band, two fundamental modes, that is, the TE‐like and TM‐like modes, degenerate and cease propagating simultaneously, indicating the possible transition of

ε_{t} μ_{t} > χ^{2}

ε_{t} μ_{t} < χ^{2}

, because the homogenization of the metamaterials holds at the Γ point . At other points (X and M) in the Brillouin zone (BZ), although affected by the Bloch scattering, the band structures remain forbidden to both TE‐like and TM‐like waves.…”

Section: Metamaterials Design and Fabricationmentioning

confidence: 99%

Spin Momentum–Locked Surface States in Metamaterials without Topological Transition

Peng

Chen

Yang

et al. 2018

Laser & Photonics Reviews

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The photonic analogy of the quantum spin Hall Effect, that is, a photonic topological insulator (PTI), is of great relevance to science and technology in optics based on the promise of scattering‐free surface states. The challenges in realizing such scattering‐free surface states in PTIs and other types of symmetry‐protected topological phases are the result of the exact symmetry needed for creating a pair of time reversal pseudo‐spin states or special boundary conditions, wherein the exact symmetry imposes strict requirements on materials or boundary conditions. Here, it is experimentally demonstrated that scattering‐free edge states can be created with neither the aforementioned exact symmetry requirements for materials nor the topological transitions. This system is constructed by simply placing together regular homogeneous metamaterials, which are characterized by highly different bianisotropies. Of the particular surface states, backward reflection would be deeply suppressed, provided that the related evanescent tail into the bulk regions vanishes shortly and that the pseudo‐spin is not flipped by the scatterers. This work gives an example of constructing scattering‐free surface states in classical systems without strict symmetry protections and may potentially stimulate various novel applications in the future.

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“…It has also been proposed that extraordinarily large absorption cross-sections of nanoscale resonators can be achieved by embedding them into a material with near-zero refractive index [269]. Recent progress in designing and fabricating low-loss zero-index metamaterials operating at various frequency ranges [270][271][272][273] makes feasible practical realization of this approach. The role of collective effects [274] caused by the interference between multiple coherent thermal sources in thermal emission enhancement, radiation wave front shaping, and focusing still needs to be revealed [275,276].…”

Section: Advances and Challenges In Fundamental Understanding And Nanmentioning

confidence: 99%

Heat meets light on the nanoscale

et al. 2016

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Abstract:We discuss the state-of-the-art and remaining challenges in the fundamental understanding and technology development for controlling light-matter interactions in nanophotonic environments in and away from thermal equilibrium. The topics covered range from the basics of the thermodynamics of light emission and absorption to applications in solar thermal energy generation, thermophotovoltaics, optical refrigeration, personalized cooling technologies, development of coherent incandescent light sources, and spinoptics.Keywords: thermal emission; absorption; spectral selectivity; angular selectivity; optical refrigeration; solar thermal energy conversion; thermophotovoltaics; nearfield heat transfer; photon density of states; thermal upconversion; radiative cooling Thermodynamics of light and heatControl and optimization of energy conversion processes involving photon absorption and radiation require detailed understanding of thermodynamic properties of radiation as well as its interaction with matter [1-5]. Historically, thermodynamic treatment of electromagnetic radiation began over a century ago with Planck applying the thermodynamic principles established for a gas of material particles to an analogous "photon gas" [1]. In particular, he showed that thermodynamic parameters, such as the energy, volume, temperature, and pressure can be applied to electromagnetic radiation, reflecting the dual wave-particle nature of photons. In this section, we will review the general thermodynamic principles governing photon propagation and interaction with matter, as well

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Conical Dispersion and Effective Zero Refractive Index in Photonic Quasicrystals

Cited by 84 publications

References 30 publications

Conical intersections for light and matter waves

Conical intersections for light and matter waves

Spin Momentum–Locked Surface States in Metamaterials without Topological Transition

Heat meets light on the nanoscale

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