58 research outputs found
Flip-chip assembly of an integrated optical sensor
For enabling low cost mass production for photonic circuits, the application of flipchip technology creates huge expectations. We report on the results of a project, having the goal to demonstrate standard packaging technology in combination with integrated optics, entailing demands and limitations different from IC technology. Mainly fiber attachment, but also special features as sensor window accessibility at the top-side of the chip are prohibiting the positioning of the optical layer stack and solder pads at the same side of the silicon wafer. Therefore, feed through technology had to be included. Compatibility issues in combining feed through technology with integrated optics processing have been solved and the feasibility of feed-through metallization and flip-chip assembly in combination with an integrated optical sensor has been demonstrated
Optical sensing in microchip capillary electrophoresis by femtosecond laser written waveguides
Capillary electrophoresis separation in an on-chip integrated microfluidic channel is typically monitored with bulky, bench-top optical excitation/detection instrumentation. Optical waveguides allow confinement and transport of light in the chip directing it to a small volume of the microfluidic channel and collecting the emitted/transmitted radiation. However, the fabrication of optical waveguides or more complex photonic components integrated with the microfluidic channels is not a straightforward process, since it requires a localized increase of the refractive index of the substrate.\ud
Recently, a novel technique has emerged for the direct writing of waveguides and photonic circuits in transparent glass substrates by focused femtosecond laser pulses.\ud
In this work we demonstrate the integration of femtosecond laser written optical waveguides into a commercial microfluidic chip. We fabricate high quality waveguides intersecting the microchannels at arbitrary positions and use them to optically address with high spatial selectivity their content. In particular, we apply our technique to integrate optical detection in microchip capillary electrophoresis. Waveguides are inscribed at the end of the separation channel in order to optically excite the different plugs reaching that point; fluorescence from the labelled biomolecules crossing the waveguide output is efficiently collected at a 90° angle by a high numerical aperture optical fiber. The sensitivity of the integrated optical detection system was first evaluated filling the chip with a dye solution, obtaining a minimum detectable concentration of 40 pM. \ud
After dynamic coating of the microchannels with an EPDMA polymer we demonstrate electrophoresis of an oligonucleotide plug with concentration down to 1 nM and wavelength-selective monitoring of on-chip separation of three fluorescent dyes. Work is in progress on separation and detection of fluorescent-labeled DNA fragments, targeting specific, diagnostically relevant regions of a template DNA, for application to the detection of chromosome aberrations
Observation of open scattering channels
The existence of fully transmissive eigenchannels ("open channels") in a
random scattering medium is a counterintuitive and unresolved prediction of
random matrix theory. The smoking gun of such open channels, namely a bimodal
distribution of the transmission efficiencies of the scattering channels, has
so far eluded experimental observation. We observe an experimental distribution
of transmission efficiencies that obeys the predicted bimodal
Dorokhov-Mello-Pereyra-Kumar distribution. Thereby we show the existence of
open channels in a linear optical scattering system. The characterization of
the scattering system is carried out by a quantum-optical readout method. We
find that missing a single channel in the measurement already prevents
detection of the open channels, illustrating why their observation has proven
so elusive until now. Our work confirms a long-standing prediction of random
matrix theory underlying wave transport through disordered systems.Comment: 9 pages including methods and supplementary materials. 3 figure
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