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Fabrication of Flexible One -Dimensional Porous Silicon Photonic Band-Gap Structures W1.3
Natalya Tokranova, Bai Xu, and James Castracane
Laterally Graded Rugate Filters in Porous Silicon W1.6
Sean E. Foss and Terje G. Finstad
Strong Light Confinement in Microporous Photonic Silicon Structures W1.7
G. Léronde, P. Reece, A. Bruyant, and M. Gal
Optical Devices Based on Anisotropically Nanostructured Silicon W1.8
J. Diener, N. Künzner , E. Gross, D. Kovalev, and M. Fujii
Silicon Micro-Photonic Structure for Ultra-Sensitive Biosensing W1.9
Bradley Schmidt, Vilson Almeida, Christina Manolatou, Stefan Preble, and Michal Lipson
Second- and Third-Harmonic Generation Spectroscopy of Coupled Microcavities Formed From All-Silicon Photonic Crystals W1.10
D.G. Gusev, I.V. Soboleva, M.G. Martemyanov, T.V. Dolgova, A.A. Fedyanin, and O.A. Aktsipetrov
Modeling of a Surface Plasmon Polariton Interferometer W2.4
Victor Coello, Thomas Søndergaard, and Sergey I. Bozhevolnyi
Subwavelength Structured Optical Elements and Resonant Grating Filters W2.5
Hisao Kikuta and Koichi Iwata
Hexagonal Lattice Photonic Crystal in Active Metallic Microcavity W2.8
H.L. Tam, R. Huber, K.F. Li, W.H. Wong, Y.B. Pun, S.K. So, J.B. Xia, and K.W. Cheah
Interaction of Periodically Arranged Point Defects in a Two Dimensional Photonic Crystal—The Photonic Analogue to a Doped Semiconductor W3.2
S. Richter, S.L. Schweizer, R. Hillebrand, C. Jamois, R.B. Wehrspohn, M. Zacharias, and U. Goesele
Jahn-Teller Effect in Photonic Crystals W3.3
Natalia Malkova and Venkatraman Gopalan
Low Loss Photonic Crystal Cladding Waveguide With Large Photonic Band Gap W3.4
Yasha Yi, Peter Bermel, Shoji Akiyama, Jessica G. Sandland, Xiaoman Duan, and Lionel. C. Kimerling
Three-Dimensional
Lithography for Rutile TiO2 Single Crystals Using Swift Heavy
Ions W3.6
Koichi Awazu, Makoto Fujimaki, Yoshimichi Ohki, and Tetsuro Komatsubara
Optical and Crystallographic Properties of Inverse Opal Photonic Crystals Grown by Atomic Layer Deposition W3.9
Jeffrey S. King, Curtis W. Neff, Dawn L. Heineman, Elton D. Graugnard, and Christopher J. Summers
Very Large Plasmon Band Shift in Strongly Coupled Metal Nanoparticle Chain Arrays W4.6
L.A. Sweatlock, J.J. Penninkhof, S.A. Maier, A. Polman, and H. Atwater
Angular
Roll-Off Dependence of Spectral Emission From a Metallodielectric
Photonic Crystal W4.7
Irina Puscasu; Martin U. Pralle, Mark P. McNeal, Nicholas Moelders,
James T. Daly, Anton C. Greenwald, Alan Ludwiszewski, Edward
A. Johnson, and William L. Schaich
Standing Wave Reflectivity in Photonic Structures Using a Scattering Type Optical Near-Field Optical Microscope W4.8
A. Bruyant, S. Aubert, G. Lérondel, S. Blaize, R. Bachelot P. Royer, and V.Minier
Photonic
Quasiperiodic Multilayers of Porous Silicon
W5.2
R. Nava, J.A. del Río, J.C. Alonso, and C. Wang
Optical Properties of Dielectric and Magnetic Photonic Crystals in the Low-Frequency Limit W5.3
Arkady Krokhin, Jesús Arriaga, and and Edgar Reyes
Photonic
Crystal Tapers for Coupling Large Ridge Waveguides to Photonic
Crystal Waveguides W5.8
Francis C. Ndi and Jean Toulouse
Phonon-Polariton Propagation, Guidance, and Control in Bulk and Patterned Thin Film Ferroelectric Crystals W5.9
David W. Ward, Eric Statz, Jaime D. Beers, Nikolay Stoyanov, Thomas Feurer, Ryan M. Roth, Richard M. Osgood, and Keith A. Nelson
Fabrication of Two-Dimensional Nonlinear Photonic Crystal by Electron Beam Lithography W5.10
Chiang Huen Kang, Ze Xiang Shen, and Sing Hai Tang
Creation and Optical Property of Microphotonic Crystals by Electrophoretic Deposition Method Using Micro-Counter Electrode W5.11
Jun-ichi Hamagami, Kazuhiro Hasegawa, and Kiyoshi Kanamura
2-D Photonic Quasicrystal in Metallic Microcavity W5.14
J.Y. Zhang, H.L. Tam, W.H. Wong, Y.B. Pun, J.B. Xia, and K.W. Cheah
Microscopic Theory of Electromagnetic Energy Transport in Nanostructured Media W5.16
Yongqiang Xue and Mark A. Ratner
Optical and Mechanical Properties of Photoassisted, Self-Assembled Nanoparticle Films W5.17
G.A. Gaddy, G.A. Miner, Diane M. Stoakley, Edward P. Locke, Rick L. Moore, John Schultz, Don Creyts, and Michael Knotts
Characterization by Variable Angle Spectroscopic Ellipsometry of Dielectric Columnar Thin Films Produced by Glancing Angle Deposition W5.19
James Gospodyn, Michael J. Brett, and Jeremy C. Sit
Anodization Time Dependent Photoluminescence Intensity of Porous Silicon W5.20
Md. N. Islam and Satyendra Kumar
Room Temperature 1.3-1.55 µ m Laser-Like Emission From Ge/Si Self-Assembled Islands in Si-Based Photonic Crystals W6.1
J-M. Lourtioz, S. David, M. El Kurdi, C. Kammerer, X. Li, S. Sauvage , A.Chelnokov, V. Le Thanh, D. Bouchier, and P. Boucaud
Ultrasmall Lasers Based on Photonic Crystal Line Defects W6.4
Toshihiko Baba
Growth and Optical Properties of 2D Photonic Crystals Based on Hexagonal GaAs/AlGaAs Pillar Arrays by Selective-Area Metalorganic Vapor Phase Epitaxy W6.6
J. Motohisa, J. Takeda, M. Inari, and T. Fukui
Design of a New Taper for Light Coupling Between a Ridge Waveguide and a Photonic Crystal Waveguide W6.7
Cécile Jamois, Torsten Geppert, and Ralf B. Wehrspohn
Dispersion Engineering of Photonic Crystal Devices W6.8
David M. Pustai, Caihua Chen, Ahmed Sharkawy, Shouyuan Shi, Janusz Murakowski, and Dennis W. Prather
Light Guiding in Low Index Materials Using High-Index-Contrast Waveguides W6.10
Vilson R. Almeida, Qianfan Xu, Roberto R. Panepucci, Carlos A. Barrios, and Michal Lipson
Dispersion
Properties of Photonic Crystal Fibers-Issues and Opportunities W7.1
J. Laegsgaard, S.E. Barkou Libori, K. Hougaard, J. Riishede,
T.T. Larsen, T. Sørensen, T. P. Hansen, K.P. Hansen, M.D.
Nielsen, J.B. Jensen, and A. Bjarklev
Design and Fabrication of Dispersion Controlled and Polarization Maintaining Photonic Crystal Fibers for Optical Communications Systems W7.2
Satoki Kawanishi, Takashi Yamamoto, Hirokazu Kubota, Masatoshi Tanaka, and Syun-ichiro Yamaguchi
Interfacial
Energy and Materials Selection Criteria in Composite Microstructured
Optical Fiber Fabrication W7.5
Shandon D. Hart and Yoel Fink
Aperiodic Lattices for Photonic Bandgap Engineering W7.8
Subhasish Chakraborty, David G. Hasko, and Robert. J. Mears
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