Light propagation in three-dimensional photonic crystals

Fabrication of micro- or nano-scale photonic devices in polymer materials to control and manipulate light propagation represents a hot topic nowadays. Compared with conventional semiconductor materials, polymers are easy to prepare and have the flexibility of incorporating active materials to realise various functionalities. As one of the most powerful tools in micro-optical fabrication, the two-photon polymerization technique has been widely employed recently to produce multifarious photonic devices, particularly the photonic crystals, which are promising candidates for integrated optical devices. In this article the recent advances in the fabrication of three-dimensional photonic devices such as diffractive optical elements, photonic crystals, and superprisms in polymer materials using the two-photon polymerization technique are reviewed. In particular, the fabrication of photonic crystals in nanocomposite polymers, which are formed by incorporating nanocrystal quantum dots into polymer materials, is demonstrated, providing an interesting physical platform for the investigation into new types of active micro-devices.

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Dispersion Engineering of Three-Dimensional Silicon Photonic Crystals: Fabrication and Applications

MRS Proceedings ◽

10.1557/proc-829-b5.9 ◽

2004 ◽

Vol 829 ◽

Author(s):

Sriram Venkataraman ◽

Garrett Schneider ◽

Janusz Murakowski ◽

Shouyan Shi ◽

Dennis W. Prather

Keyword(s):

Photonic Crystals ◽

Light Propagation ◽

Three Dimensional ◽

Dispersion Engineering ◽

Silicon Photonic ◽

Planar Silicon ◽

Control Light ◽

Spherical Voids ◽

And Control ◽

Interconnect Technology

ABSTRACTIn this paper, we propose the design and fabrication of buried silicon optical interconnect technology, the sub-surface silicon optical bus (S3B). The proposed approach relies on engineering the dispersion properties of embedded silicon three-dimensional photonic crystals to create sub-micron routing channels and control light propagation. Further, we present a method for the fabrication of buried three-dimensional (3D) photonic-crystal structures using conventional planar silicon micromachining. The method utilizes a single planar etch mask coupled with time-multiplexed, sidewall-passivating, deep anisotropic reactive-ion etching, to create an array of spherical voids with three-dimensional symmetry. Preliminary results are presented that demonstrate the feasibility of realizing chip-scale optical interconnects using our proposed approach.

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Time-resolved broadband analysis of slow-light propagation and superluminal transmission of electromagnetic waves in three-dimensional photonic crystals

Physical Review B ◽

10.1103/physrevb.71.155110 ◽

2005 ◽

Vol 71 (15) ◽

Cited By ~ 9

Author(s):

J. Gómez Rivas ◽

A. Farré Benet ◽

J. Niehusmann ◽

P. Haring Bolivar ◽

H. Kurz

Keyword(s):

Photonic Crystals ◽

Electromagnetic Waves ◽

Light Propagation ◽

Slow Light ◽

Three Dimensional ◽

Time Resolved

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Finite Element Analysis of Photon Density of States for Two-dimensional Photonic Crystals with In-plane Light Propagation

PIERS Online ◽

10.2529/piers061007113530 ◽

2007 ◽

Vol 3 (3) ◽

pp. 315-319 ◽

Cited By ~ 1

Author(s):

Ming-Chieh Lin ◽

R. F. Jao

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Photonic Crystals ◽

Density Of States ◽

Light Propagation ◽

Photon Density ◽

Two Dimensional ◽

Element Analysis ◽

Plane Light

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Other topics

10.1093/oso/9780198824442.003.0007 ◽

2018 ◽

Author(s):

Ted Janssen ◽

Gervais Chapuis ◽

Marc de Boissieu

Keyword(s):

Photonic Crystals ◽

Crystal Morphology ◽

Three Dimensional ◽

Icosahedral Quasicrystal ◽

Crystal Surfaces ◽

Decagonal Quasicrystal ◽

System A ◽

Fundamental Law ◽

Quasiperiodic Systems ◽

Aperiodic Crystals

The law of rational indices to describe crystal faces was one of the most fundamental law of crystallography and is strongly linked to the three-dimensional periodicity of solids. This chapter describes how this fundamental law has to be revised and generalized in order to include the structures of aperiodic crystals. The generalization consists in using for each face a number of integers, with the number corresponding to the rank of the structure, that is, the number of integer indices necessary to characterize each of the diffracted intensities generated by the aperiodic system. A series of examples including incommensurate multiferroics, icosahedral crystals, and decagonal quaiscrystals illustrates this topic. Aperiodicity is also encountered in surfaces where the same generalization can be applied. The chapter discusses aperiodic crystal morphology, including icosahedral quasicrystal morphology, decagonal quasicrystal morphology, and aperiodic crystal surfaces; magnetic quasiperiodic systems; aperiodic photonic crystals; mesoscopic quasicrystals, and the mineral calaverite.

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