Author
Listed:
- Alvaro Blanco
(60 Saint George Street, University of Toronto
Unidad Asociada (CSIC-UPV) Universidad Politécnica
Instituto de Ciencia de Materiales de Madrid (CSIC))
- Emmanuel Chomski
(80 Saint George Street, University of Toronto)
- Serguei Grabtchak
(60 Saint George Street, University of Toronto)
- Marta Ibisate
(Unidad Asociada (CSIC-UPV) Universidad Politécnica
Instituto de Ciencia de Materiales de Madrid (CSIC))
- Sajeev John
(60 Saint George Street, University of Toronto)
- Stephen W. Leonard
(60 Saint George Street, University of Toronto)
- Cefe Lopez
(Unidad Asociada (CSIC-UPV) Universidad Politécnica
Instituto de Ciencia de Materiales de Madrid (CSIC))
- Francisco Meseguer
(Unidad Asociada (CSIC-UPV) Universidad Politécnica
Instituto de Ciencia de Materiales de Madrid (CSIC))
- Hernan Miguez
(Unidad Asociada (CSIC-UPV) Universidad Politécnica
Instituto de Ciencia de Materiales de Madrid (CSIC))
- Jessica P. Mondia
(60 Saint George Street, University of Toronto)
- Geoffrey A. Ozin
(80 Saint George Street, University of Toronto)
- Ovidiu Toader
(60 Saint George Street, University of Toronto)
- Henry M. van Driel
(60 Saint George Street, University of Toronto)
Abstract
Photonic technology, using light instead of electrons as the information carrier, is increasingly replacing electronics in communication and information management systems. Microscopic light manipulation, for this purpose, is achievable through photonic bandgap materials1,2, a special class of photonic crystals in which three-dimensional, periodic dielectric constant variations controllably prohibit electromagnetic propagation throughout a specified frequency band. This can result in the localization of photons3,4,5,6, thus providing a mechanism for controlling and inhibiting spontaneous light emission that can be exploited for photonic device fabrication. In fact, carefully engineered line defects could act as waveguides connecting photonic devices in all-optical microchips7, and infiltration of the photonic material with suitable liquid crystals might produce photonic bandgap structures (and hence light-flow patterns) fully tunable by an externally applied voltage8,9,10. However, the realization of this technology requires a strategy for the efficient synthesis of high-quality, large-scale photonic crystals with photonic bandgaps at micrometre and sub-micrometre wavelengths, and with rationally designed line and point defects for optical circuitry. Here we describe single crystals of silicon inverse opal with a complete three-dimensional photonic bandgap centred on 1.46 µm, produced by growing silicon inside the voids of an opal template of close-packed silica spheres that are connected by small ‘necks’ formed during sintering, followed by removal of the silica template. The synthesis method is simple and inexpensive, yielding photonic crystals of pure silicon that are easily integrated with existing silicon-based microelectronics.
Suggested Citation
Alvaro Blanco & Emmanuel Chomski & Serguei Grabtchak & Marta Ibisate & Sajeev John & Stephen W. Leonard & Cefe Lopez & Francisco Meseguer & Hernan Miguez & Jessica P. Mondia & Geoffrey A. Ozin & Ovidi, 2000.
"Large-scale synthesis of a silicon photonic crystal with a complete three-dimensional bandgap near 1.5 micrometres,"
Nature, Nature, vol. 405(6785), pages 437-440, May.
Handle:
RePEc:nat:nature:v:405:y:2000:i:6785:d:10.1038_35013024
DOI: 10.1038/35013024
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Cited by:
- Zhou, Yi-Peng & Yang, Pei-Xin & Wang, Liang-Xu & Xu, Jia-Chen & He, Ya-Ling, 2023.
"Full spectrum photon management of photonic crystal-based aerogels to achieve the multiscale multiphysics regulations and optimizations of PV-TE/T systems,"
Renewable Energy, Elsevier, vol. 217(C).
- Jyh-Herng Chen & Yu-Hao Chang & Chaochin Su & Kai-Chung Hsu, 2021.
"The Stabilization of Waste Funnel Glass of CRT by SiO 2 Film Coating Technique,"
Sustainability, MDPI, vol. 13(16), pages 1-12, August.
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