Rewritable photonic circuits

Intonti, Francesca; Vignolini, Silvia; Türck, V.; Colocci, M.; Bettotti, Paolo; Pavesi, L.; Schweizer, Stefan L.; Wehrspohn, Ralf B.; Wiersma, Diederik S.

doi:10.1063/1.2392720

Cited by 120 publications

(65 citation statements)

References 25 publications

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“…Such a structure can be used as a sensor, whose principle of operation is based on the cut-o wavelength shift caused by the in ltration of the holes. In ltration can be performed by various selective in ltration techniques, which have been experimentally demonstrated, such as using an integrated micro uidic circuit [24], an actuated microtip [25] or micropipette [26] with a high precision and good reproducibility.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of Refractive Index Sensitivity in Photonic Crystal Waveguide-Based Sensors by Selective Infiltration

Bagci

Akaoglu

2013

Acta Phys. Pol. A

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We present a liquid refractive index sensor based on a photonic crystal waveguide slab structure. Sensing mechanism employed in this study is based on the shift in cut-o wavelength as the lattice holes are selectively in ltrated. Three-dimensional plane-wave expansion and nite-di erence time-domain methods are used to determine the band structure and transmission spectra, respectively. First, the sensitivity of the device is analyzed for the structure where only the rst rows of holes adjacent to the line-defect are in ltrated. In addition, this analysis is repeated for a range of hole diameters. Second, the e ects of in ltrated holes which are placed in the line-defect are investigated. As these in ltrated central holes are introduced, the proposed device exhibits 5.3 times improved sensitivity.

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Section: Introductionmentioning

confidence: 99%

Enhancement of Refractive Index Sensitivity in Photonic Crystal Waveguide-Based Sensors by Selective Infiltration

Bagci

Akaoglu

2013

Acta Phys. Pol. A

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“…Therefore, postprocessing tuning techniques able to compensate for fabrication imperfections are particularly demanded. Various postprocessing tuning techniques have been demonstrated, such as differential thermal tuning, 7,8 wet chemical digital etching, 9 atomic layer deposition, 10 atomic force microscope nano-oxidation, 11 liquid crystal infiltration, 12 and photodarkening of a chalcogenide glass placed on top of the microcavity. 13 Most of these techniques either modify the properties of the whole sample, which prevents the local tuning of a single nanocavity, or need extra materials and processing tools.…”

mentioning

confidence: 99%

Local tuning of photonic crystal nanocavity modes by laser-assisted oxidation

Lee

Kiravittaya

Kumar

et al. 2009

Applied Physics Letters

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The authors demonstrate a simple method to achieve local tuning of optical modes in GaAs photonic crystal nanocavities by continuous wave laser-assisted oxidation in air atmosphere. By irradiation with a focused laser beam at power levels of a few tens of milliwatts, photonic crystal nanocavity modes shift to shorter wavelengths by up to 2.5 nm. The mode shifts can be controlled either by varying the laser power or by iterating laser-assisted oxidation steps and are well explained by finite-element-method and finite-difference time-domain simulations. This method provides a simple route to achieve fine spectral tuning of individual nanocavities for photonic devices.

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“…8 However, the nanometer-scale precision required to realize sophisticated and optimized geometries eventually becomes a limiting factor in achieving high-Q cavities, as pointed out by Asano et al 9 Recently, several groups have reported demonstrations of postprocessed PCS structures, granting them the flexibility to tune or reconfigure device properties to suit various applications at any time after the PCS is fabricated. [10][11][12][13] In particular, Intonti et al introduced a "pixel by pixel" approach for writing and rewriting PCS defect structures via fluid infiltration. 12 Theoretical results of Tomljenovic-Hanic et al showed that high Q-factor cavities could be achieved in PCSs from fluid infiltration 14 by forming doubleheterostructured geometries, providing an integrated optofluidic sensing architecture.…”

mentioning

confidence: 99%

“…[10][11][12][13] In particular, Intonti et al introduced a "pixel by pixel" approach for writing and rewriting PCS defect structures via fluid infiltration. 12 Theoretical results of Tomljenovic-Hanic et al showed that high Q-factor cavities could be achieved in PCSs from fluid infiltration 14 by forming doubleheterostructured geometries, providing an integrated optofluidic sensing architecture.…”

mentioning

confidence: 99%

Microfluidic photonic crystal double heterostructures

Smith

Lee

et al. 2007

Applied Physics Letters

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We demonstrate postprocessed and reconfigurable photonic crystal double-heterostructure cavities via selective fluid infiltration. We experimentally investigate the microfluidic cavities via evanescent probing from a tapered fiber at telecommunication wavelengths. Fabry-Pérot fringes associated with modes of the induced cavity are in good agreement with the theory. We also demonstrate a cavity with quality factor Q=4300. Our defect-writing technique does not require nanometer-scale alterations in lattice geometry and may be undertaken at any time after photonic crystal waveguide fabrication.

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Rewritable photonic circuits

Cited by 120 publications

References 25 publications

Enhancement of Refractive Index Sensitivity in Photonic Crystal Waveguide-Based Sensors by Selective Infiltration

Enhancement of Refractive Index Sensitivity in Photonic Crystal Waveguide-Based Sensors by Selective Infiltration

Local tuning of photonic crystal nanocavity modes by laser-assisted oxidation

Microfluidic photonic crystal double heterostructures

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