Complete three-dimensional band gap in macroporous silicon photonic crystals

AbstractWe demonstrate two ways in which the optical band-gap of a 2-D macroporous silicon photonic crystal can be tuned. In the first method the temperature dependence of the refractive index of an infiltrated nematic liquid crystal is used to tune the high frequency edge of the photonic band gap by up to 70 nm as the temperature is increased from 35 to 59°C. In a second technique we have optically pumped the silicon backbone using 150 fs, 800 nm pulses, injecting high density electron hole pairs. Through the induced changes to the dielectric constant via the Drude contribution we have observed shifts up to 30 nm of the high frequency edge of a band-gap.

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Embedded cavities and waveguides in three-dimensional silicon photonic crystals

Nature Photonics ◽

10.1038/nphoton.2007.252 ◽

2007 ◽

Vol 2 (1) ◽

pp. 52-56 ◽

Cited By ~ 224

Author(s):

Stephanie A. Rinne ◽

Florencio García-Santamaría ◽

Paul V. Braun

Keyword(s):

Photonic Crystals ◽

Three Dimensional ◽

Silicon Photonic

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Current status of three-dimensional silicon photonic crystals operating at infrared wavelengths

10.1117/12.391476 ◽

2000 ◽

Cited By ~ 1

Author(s):

Shawn-Yu Lin ◽

James G. Fleming ◽

Mihail M. Sigalas ◽

Rana Biswas ◽

Kai M. Ho

Keyword(s):

Photonic Crystals ◽

Three Dimensional ◽

Current Status ◽

Silicon Photonic ◽

Infrared Wavelengths

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Linear and Non‐linear Optical Experiments Based on Macroporous Silicon Photonic Crystals

Nanophotonic Materials ◽

10.1002/9783527621880.ch9 ◽

2008 ◽

pp. 157-181 ◽

Cited By ~ 1

Author(s):

Ralf B. Wehrspohn ◽

Stefan L. Schweizer ◽

Vahid Sandoghdar

Keyword(s):

Photonic Crystals ◽

Macroporous Silicon ◽

Silicon Photonic ◽

Non Linear ◽

Linear Optical

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Electromagnetic properties of photonic crystals with diamond structure containing defects

Journal of Materials Research ◽

10.1557/jmr.2003.0309 ◽

2003 ◽

Vol 18 (9) ◽

pp. 2214-2220 ◽

Cited By ~ 5

Author(s):

Shingo Kanehira ◽

Soshu Kirihara ◽

Yoshinari Miyamoto ◽

Kazuaki Sakoda ◽

Mitsuo Wada Takeda

Keyword(s):

Photonic Crystals ◽

Band Gap ◽

Photonic Band Gap ◽

Three Dimensional ◽

Expansion Method ◽

Electromagnetic Properties ◽

Diamond Structure ◽

Multiple Reflections ◽

Air Cavity ◽

Photonic Band

Three-dimensional photonic crystals with a diamond structure, which are composed of the TiO2-based ceramic particles dispersed in an epoxy lattice, were fabricated by stereolithography. The diamond structure showed a photonic band gap in the 14.3–17.0 GHz range along the Γ-K 〈110〉 direction, which is close to the band calculation using the plain wave expansion method. Two types of lattice defects—air cavity and dielectric cavity—were introduced into the diamond structure by removing a unit cell of diamond structure or inserting a block of the lattice medium into the air cavity. The transmission of millimeter waves affected by multiple reflections at the defects was measured in the photonic band gap. Resonant frequencies in the defects were calculated and compared with the measurement results.

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Selective Transmission of Electromagnetic Wave by Using Diamond Photonic Crystals with Graded Lattice Spacing

Advances in Science and Technology ◽

10.4028/www.scientific.net/ast.45.1139 ◽

2006 ◽

Vol 45 ◽

pp. 1139-1144

Author(s):

Soshu Kirihara ◽

Yoshinari Miyamoto

Keyword(s):

Photonic Crystals ◽

Band Gap ◽

Electromagnetic Waves ◽

Lattice Spacing ◽

Three Dimensional ◽

Dielectric Constants ◽

Microwave Antenna ◽

Diamond Structure ◽

Band Calculation ◽

Graded Lattice

Three-dimensional electromagnetic or photonic crystals with periodic variations of the dielectric constants were fabricated by using a rapid prototyping method called stereolithography. Millimeter-order epoxy lattices with a diamond structure were designed to reflect electromagnetic waves by forming an electromagnetic band gap in GHz range. Titania based ceramic particles were dispersed into the lattice to control the dielectric constant. The diamond lattice structures formed the perfect band gap reflecting electromagnetic waves for all directions. The location of the band gap agreed with the band calculation using the plane wave propagation method. The diamond structures with graded lattice spacing were successfully fabricated as well, resulting in the directional transmission of microwaves. The stretching ratio of the lattice spacing in the crystal structure was changed according to the electromagnetic band calculation. A microwave antenna head composed of the diamond structure with graded lattice spacing was fabricated which achieved the unidirectional transmission.

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