Introducing Defects in 3D Photonic Crystals: State of the Art

Braun, Paul V.; Rinne, Stephanie A.; García-Santamaría, Florencio

doi:10.1002/adma.200600769

Cited by 246 publications

(181 citation statements)

References 133 publications

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“…This surface resonance is demonstrated for two different three-dimensional (3D) photonic crystals and is expected to occur in a large number of photonic crystal systems including those made by holography, phase mask lithography, two-photon polymerization in addition to the systems presented here. 9 Such resonances prohibit coupling light to optically active features including resonant cavities or embedded defects 10 within the structure since all photons are reflected at the surface. Likewise, slow photon propagation, negative refraction or super-prism effects would also be negatively affected since they require coupling of photons to specific optical modes.…”

Section: Introductionmentioning

confidence: 99%

Optical surface resonance may render photonic crystals ineffective

García-Santamaría

Nelson

2007

Phys. Rev. B

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In this work we identify and study the presence of extremely intense surface resonances that frustrate the coupling of photons into a photonic crystal over crucial energy ranges. The practical utility of photonic crystals demands the capability to exchange photons with the external medium, therefore, it is essential to understand the cause of these surface resonances and a route to their elimination. We demonstrate that by modifying the surface geometry it is possible to tune the optical response or eliminate the resonances to enable full exploitation of the photonic crystal.

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Section: Introductionmentioning

confidence: 99%

Optical surface resonance may render photonic crystals ineffective

García-Santamaría

Nelson

2007

Phys. Rev. B

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“…6,7 Among them, self-assembled PhCs have been studied in detail due to their low cost of fabrication and ease of preparation, with artificial opals 1,2,8,9 being especially popular. Synthetic opals provide versatile systems that can be infiltrated by vapour phases, 10 or solutions, 11 thereby enabling the investigation of a variety of photonic effects and especially the fine-tuning of the optical properties. 12 These include the modification of the emission spectra and of the radiative rates, 13,14 optical switching, 15 and Fano resonances.…”

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confidence: 99%

Fluorescent polystyrene photonic crystals self-assembled with water-soluble conjugated polyrotaxanes

et al. 2013

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We demonstrate control of the photoluminescence spectra and decay rates of water-soluble green-emitting conjugated polyrotaxanes by incorporating them in polystyrene opals with a stop-band spectrally tuned on the rotaxane emission (405–650 nm). We observe a suppression of the luminescence within the photonic stop-band and a corresponding enhancement of the high-energy edge (405–447 nm). Time-resolved measurements reveal a wavelength-dependent modification of the emission lifetime, which is shortened at the high-energy edge (by ∼11%, in the range 405–447 nm), but elongated within the stop-band (by ∼13%, in the range 448–482 nm). We assign both effects to the modification of the density of photonic states induced by the photonic crystal band structure. We propose the growth of fluorescent composite photonic crystals from blends of “solvent-compatible” non-covalently bonded nanosphere-polymer systems as a general method for achieving a uniform distribution of polymeric dopants in three-dimensional self-assembling photonic structures

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“…Three-dimensional periodic dielectric structures have distinctive optical properties [46][47][48] and are of great interest in designing new functionalities in optoelectronics. They may also possess promising thermoelectric properties.…”

Section: B Three-dimensional Structuresmentioning

confidence: 99%

Thermal transport in 2- and 3-dimensional periodic “holey” nanostructures

Sadhu

Ganta

et al. 2014

AIP Advances

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Understanding thermal transport in two- and three-dimensional periodic “holey” nanostructures is important for realizing applications of these structures in thermoelectrics, photonics and batteries. In terms of continuum heat diffusion physics, the effective medium theory provides the framework for obtaining the effective thermal conductivity of such structures. However, recently measured nanostructures possess thermal conductivities well below these continuum predictions. In some cases, their thermal conductivities are even lower than predictions that account for sub-continuum phonon transport. We analyze current understanding of thermal transport in such structures, discussing the various theories, the measurements and the insights gained from comparing the two.

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Introducing Defects in 3D Photonic Crystals: State of the Art

Cited by 246 publications

References 133 publications

Optical surface resonance may render photonic crystals ineffective

Optical surface resonance may render photonic crystals ineffective

Fluorescent polystyrene photonic crystals self-assembled with water-soluble conjugated polyrotaxanes

Thermal transport in 2- and 3-dimensional periodic “holey” nanostructures

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