R. Casquel

Slot-waveguide biochemical sensor

We report an experimental demonstration of an integrated biochemical sensor based on a slot-waveguide microring resonator. The microresonator is fabricated on a Si3N4-SiO2 platform and operates at a wavelength of 1.3 microm. The transmission spectrum of the sensor is measured with different ambient refractive indices ranging from n=1.33 to 1.42. A linear shift of the resonant wavelength with increasing ambient refractive index of 212 nm/refractive index units (RIU) is observed. The sensor detects a minimal refractive index variation of 2x10(-4) RIU.

Demonstration of slot-waveguide structures on silicon nitride / silicon oxide platform

We report on the first demonstration of guiding light in vertical slot-waveguides on silicon nitride/silicon oxide material system. Integrated ring resonators and Fabry-Perot cavities have been fabricated and characterized in order to determine optical features of the slot-waveguides. Group index behavior evidences guiding and confinement in the low-index slot region at O-band (1260-1370nm) telecommunication wavelengths. Propagation losses of <20 dB/cm have been measured for the transverse-electric mode of the slot-waveguides.

Slot-waveguide biochemical sensor: erratum

The group index, instead of the effective index, is used to analyze the performance of a Si3N4–SiO2 slot-waveguide microring refractive index sensor [Opt. Lett. 32, 3080 (2007)]. Assuming that the slot is fully filled with liquid, excellent agreement is found between experimental results and calculations.

Bulk sensing performance comparison between silicon dioxide and resonant high aspect ratio nanopillars arrays fabricated by means of interference lithography

In this work we present the refractive index sensing performance comparison between resonant (R-NPs) and silicon dioxide (SiO2-NPs) high-aspect ratio nano-pillars arrays. Both arrays have been fabricated by laser interference lithography and reactive ion etching. The R-NPs are made by a multilayer of silicon oxide and silicon nitride distributed to act as a vertical resonant cavity with two Bragg reflectors. Several chips containing eight periodic arrays of R-NPs and SiO2-NPs were implemented following the presented fabrication process, having a height in the order of 2.5 μm, a diameter in the order of 200 nm, different pitches and aspect ratio up to 9.8. Finally, the optical responses of these arrays were measured by infiltration of fluids with different refractive indexes. The main conclusion is that sensitivity obtained for the R-NPs is more than two times higher in comparison with the SiO2-NPs sensitivity (3724 cm−1/RIU and 1652 cm−1/RIU, respectively).

Arrays of resonant nanopillars for biochemical sensing

In this Letter, we demonstrate for the first time the experimental capability for the biochemical sensing of resonant nanopillars (RNPs) arrays. These arrays are fabricated over a glass substrate and are optically integrated from the backside of this substrate. The reflectivity profiles of the RNPs arrays are measured by infiltrating different ethanol fractions in water in order to evaluate the optical response for the different refractive indexes, which range from 1.330 to 1.342. A linear fit of the resonant modes shift is observed as a function of the bulk refractive index of the liquid infiltrated. For the type of transducer analyzed, a relative sensitivity of 10017  cm(-1)/Refractive Index Unit (RIU) is achieved, allowing us to reach a competitive Limit of Detection (LoD) in the order of 1×10(-5)  RIU.

Direct laser interference patterning (DLIP) technique applied to the development of optical biosensors based on biophotonic sensing cells (bicells)

Direct Laser Interference Patterning (DLIP) technique were employed in the development of optical biosensors based on Biophotonic Sensing Cells (BICELLs). Fabrication was carried out by laser patterning of cross-linked SU-8 thin films deposited both on silicon (Si) and glass substrates. Different photonic structures were developed in order to prove their biosensing suitability by mean of and indirect immunoassay of Bovine Serum Albumin (BSA)/anti-BSA, demonstrating that patterned areas improve the sensitivity in comparison with non-patterned sensing surfaces.