Damien Bernier scite author profile

This paper addresses the problem of a photonic crystal (PhC) superprism design for coarse wavelength division multiplexing (CWDM) application. The proposed solution consists in using a PhC structure that presents an efficient balance between the wavelength dispersion and the beam divergence. It is shown that a bidimensional rhombohedral lattice PhC displays both a high beam collimation and an important wavelength dependant angular dispersion. We report the design, fabrication and experimental demonstration of a 4-channel optical demultiplexer with a spectral spacing of 25 nm and a cross-talk level of better than -16 dB using a 2800 microm(2) PhC region. The minimum of insertion losses of the demultiplexer is less than 2 dB. The obtained results present an important milestone toward PhC devices for practical applications.

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Dye-based photonic sensing systems

Aparicio

Alcaire

González‐Elipe

et al. 2016

Sensors and Actuators B: Chemical

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PDMS microfluidics developed for polymer based photonic biosensors

et al. 2014

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Abstract:In this work, advances in the fabrication technology and functional analysis of a polymer microfluidic system -as a significant part of a developed polymer photonic biosensor -are reported. Robust and cost-effective microfluidics in PDMS including sample preparation functions is designed and realized by using SU-8 moulding replica. Surface modification strategies using Triton X-100 and PDMS-PEO and their effect on device sealing and non-specific protein adsorption are investigated by contact angle measurement and in situ fluorescence microscopy.Response to Reviewers: Dear Editors and Reviewers, First of all, thank You for the effort in improving our paper. Regarding the reviewer comments, we made the following modifications regarding the latest version of the manuscript submitted. The modifications and the required supplements are submitted in pdf format with the revised manuscript.Thank You again for the efforts to improve our manuscript. Regards, Péter Fürjes

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Near-field observation of beam steering in a photonic crystal superprism

et al. 2011

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The optical near-field technique is applied to provide a direct experimental observation of the refracted beam propagation inside a photonic crystal structure displaying a superprism effect. The obtained results show a 35° light beam angle deviation for a wavelength variation from 1500 to 1600 nm. The experimentally determined beam divergence is in good agreement with modeling predictions and previously performed transmittance experiments. A marked self-collimation propagation over a broad 20 nm wide spectral range centered at λ=1550 nm is experimentally demonstrated. The developed technique opens promising perspectives for the invisibility cloaking structures investigation.

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Damien Bernier

Compact, low cross-talk CWDM demultiplexer using photonic crystal superprism

Dye-based photonic sensing systems

PDMS microfluidics developed for polymer based photonic biosensors

Near-field observation of beam steering in a photonic crystal superprism

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