Silicon photonic crystal nanostructures for refractive index sensing

D. F. Dorfner; T. Hürlimann; T. Zabel; L. H. Frandsen; G. Abstreiter; J. J. Finley

doi:10.1063/1.3009203

Silicon photonic crystal nanostructures for refractive index sensing

D. F. Dorfner, T. Hürlimann, T. Zabel, L. H. Frandsen, G. Abstreiter, J. J. Finley

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102 Scopus citations

Abstract

The authors present the fabrication and optical investigation of silicon on insulator photonic crystal drop filters for use as refractive index sensors. Two types of defect nanocavities (L3 and H1-r) are embedded between two W1 photonic crystal waveguides to evanescently route light at the cavity mode frequency between input and output waveguides. Optical characterization of the structures in air and various liquids demonstrates detectivities in excess of Δn/n=0.018 and Δn/n=0.006 for the H1-r and L3 cavities, respectively. The measured cavity frequencies and detector refractive index responsivities are in good agreement with simulations, demonstrating that the method provides a background free transducer signal with frequency selective addressing of a specific area of the sensor chip.

Original language	English
Article number	181103
Journal	Applied Physics Letters
Volume	93
Issue number	18
DOIs	https://doi.org/10.1063/1.3009203
State	Published - 2008

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title = "Silicon photonic crystal nanostructures for refractive index sensing",

abstract = "The authors present the fabrication and optical investigation of silicon on insulator photonic crystal drop filters for use as refractive index sensors. Two types of defect nanocavities (L3 and H1-r) are embedded between two W1 photonic crystal waveguides to evanescently route light at the cavity mode frequency between input and output waveguides. Optical characterization of the structures in air and various liquids demonstrates detectivities in excess of Δn/n=0.018 and Δn/n=0.006 for the H1-r and L3 cavities, respectively. The measured cavity frequencies and detector refractive index responsivities are in good agreement with simulations, demonstrating that the method provides a background free transducer signal with frequency selective addressing of a specific area of the sensor chip.",

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T1 - Silicon photonic crystal nanostructures for refractive index sensing

AU - Dorfner, D. F.

AU - Hürlimann, T.

AU - Zabel, T.

AU - Frandsen, L. H.

AU - Abstreiter, G.

AU - Finley, J. J.

PY - 2008

Y1 - 2008

N2 - The authors present the fabrication and optical investigation of silicon on insulator photonic crystal drop filters for use as refractive index sensors. Two types of defect nanocavities (L3 and H1-r) are embedded between two W1 photonic crystal waveguides to evanescently route light at the cavity mode frequency between input and output waveguides. Optical characterization of the structures in air and various liquids demonstrates detectivities in excess of Δn/n=0.018 and Δn/n=0.006 for the H1-r and L3 cavities, respectively. The measured cavity frequencies and detector refractive index responsivities are in good agreement with simulations, demonstrating that the method provides a background free transducer signal with frequency selective addressing of a specific area of the sensor chip.

AB - The authors present the fabrication and optical investigation of silicon on insulator photonic crystal drop filters for use as refractive index sensors. Two types of defect nanocavities (L3 and H1-r) are embedded between two W1 photonic crystal waveguides to evanescently route light at the cavity mode frequency between input and output waveguides. Optical characterization of the structures in air and various liquids demonstrates detectivities in excess of Δn/n=0.018 and Δn/n=0.006 for the H1-r and L3 cavities, respectively. The measured cavity frequencies and detector refractive index responsivities are in good agreement with simulations, demonstrating that the method provides a background free transducer signal with frequency selective addressing of a specific area of the sensor chip.

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JO - Applied Physics Letters

JF - Applied Physics Letters

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Silicon photonic crystal nanostructures for refractive index sensing

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