We studied various types of 2D and 3D Si-based photonic crystal structures that are promising for future photonic integrated circuit application. With regard to 2D SOI photonic crystal slabs, we confirmed the formation of a wide photonic bandgap at optical communication wavelengths, and used structural tuning to realize efficient single-mode line-defect waveguides operating within the bandgap. As regards 3D photonic crystals, we used a combination of lithography and the autocloning deposition method to realize complicated 3D structures. We used this strategy to fabricate 3D full-gap photonic crystals and 3D/2D hybrid photonic crystals.
Masaya NOTOMI
Akihiko SHINYA
Eiichi KURAMOCHI
Itaru YOKOHAMA
Chiharu TAKAHASHI
Koji YAMADA
Jun-ichi TAKAHASHI
Takayuki KAWASHIMA
Shojiro KAWAKAMI
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Masaya NOTOMI, Akihiko SHINYA, Eiichi KURAMOCHI, Itaru YOKOHAMA, Chiharu TAKAHASHI, Koji YAMADA, Jun-ichi TAKAHASHI, Takayuki KAWASHIMA, Shojiro KAWAKAMI, "Si-Based Photonic Crystals and Photonic-Bandgap Waveguides" in IEICE TRANSACTIONS on Electronics,
vol. E85-C, no. 4, pp. 1025-1032, April 2002, doi: .
Abstract: We studied various types of 2D and 3D Si-based photonic crystal structures that are promising for future photonic integrated circuit application. With regard to 2D SOI photonic crystal slabs, we confirmed the formation of a wide photonic bandgap at optical communication wavelengths, and used structural tuning to realize efficient single-mode line-defect waveguides operating within the bandgap. As regards 3D photonic crystals, we used a combination of lithography and the autocloning deposition method to realize complicated 3D structures. We used this strategy to fabricate 3D full-gap photonic crystals and 3D/2D hybrid photonic crystals.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/e85-c_4_1025/_p
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@ARTICLE{e85-c_4_1025,
author={Masaya NOTOMI, Akihiko SHINYA, Eiichi KURAMOCHI, Itaru YOKOHAMA, Chiharu TAKAHASHI, Koji YAMADA, Jun-ichi TAKAHASHI, Takayuki KAWASHIMA, Shojiro KAWAKAMI, },
journal={IEICE TRANSACTIONS on Electronics},
title={Si-Based Photonic Crystals and Photonic-Bandgap Waveguides},
year={2002},
volume={E85-C},
number={4},
pages={1025-1032},
abstract={We studied various types of 2D and 3D Si-based photonic crystal structures that are promising for future photonic integrated circuit application. With regard to 2D SOI photonic crystal slabs, we confirmed the formation of a wide photonic bandgap at optical communication wavelengths, and used structural tuning to realize efficient single-mode line-defect waveguides operating within the bandgap. As regards 3D photonic crystals, we used a combination of lithography and the autocloning deposition method to realize complicated 3D structures. We used this strategy to fabricate 3D full-gap photonic crystals and 3D/2D hybrid photonic crystals.},
keywords={},
doi={},
ISSN={},
month={April},}
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TY - JOUR
TI - Si-Based Photonic Crystals and Photonic-Bandgap Waveguides
T2 - IEICE TRANSACTIONS on Electronics
SP - 1025
EP - 1032
AU - Masaya NOTOMI
AU - Akihiko SHINYA
AU - Eiichi KURAMOCHI
AU - Itaru YOKOHAMA
AU - Chiharu TAKAHASHI
AU - Koji YAMADA
AU - Jun-ichi TAKAHASHI
AU - Takayuki KAWASHIMA
AU - Shojiro KAWAKAMI
PY - 2002
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E85-C
IS - 4
JA - IEICE TRANSACTIONS on Electronics
Y1 - April 2002
AB - We studied various types of 2D and 3D Si-based photonic crystal structures that are promising for future photonic integrated circuit application. With regard to 2D SOI photonic crystal slabs, we confirmed the formation of a wide photonic bandgap at optical communication wavelengths, and used structural tuning to realize efficient single-mode line-defect waveguides operating within the bandgap. As regards 3D photonic crystals, we used a combination of lithography and the autocloning deposition method to realize complicated 3D structures. We used this strategy to fabricate 3D full-gap photonic crystals and 3D/2D hybrid photonic crystals.
ER -