H. McIntosh scite author profile

A complete photonic wire molecular biosensor microarray chip architecture and supporting instrumentation is described. Chip layouts with 16 and 128 independent sensors have been fabricated and tested, where each sensor can provide an independent molecular binding curve. Each sensor is 50 μm in diameter, and consists of a millimeter long silicon photonic wire waveguide folded into a spiral ring resonator. An array of 128 sensors occupies a 2 × 2 mm2 area on a 6 × 9 mm2 chip. Microfluidic sample delivery channels are fabricated monolithically on the chip. The size and layout of the sensor array is fully compatible with commercial spotting tools designed to independently functionalize fluorescence based biochips. The sensor chips are interrogated using an instrument that delivers sample fluid to the chip and is capable of acquiring up to 128 optical sensor outputs simultaneously and in real time. Coupling light from the sensor chip is accomplished through arrays of sub-wavelength surface grating couplers, and the signals are collected by a fixed two-dimensional detector array. The chip and instrument are designed so that connection of the fluid delivery system and optical alignment are automated, and can be completed in a few seconds with no active user input. This microarray system is used to demonstrate a multiplexed assay for serotyping E. coli bacteria using serospecific polyclonal antibody probe molecules.

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Sensitive, fast-responding passive electrostatic radon monitor

Griffin

Kochermin

Tarr

et al. 2011

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A second generation fast-responding passive radon detector using electrostatic concentration and enhanced readout electronics has been designed, built and tested. This detector utilizes the custom α-detecting IC called αRAM. In order to assess the response time, simulations were performed to analyze the turn-on transient of the detector. In an ambient with constant radon concentration, simulations indicate 1.44 hours will be required for the detector to reach 90% of its maximum count rate. This result is consistent with experimental findings using both first and second generation passive radon detectors.

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Silicon photonic wire biosensors: Sensing, instrumentation, and applications

Janz

Densmore

et al. 2011

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H. McIntosh

Denitrification losses from an intensively managed sub-tropical pasture – Impact of soil moisture on the partitioning of N 2 and N 2 O emissions

Photonic wire biosensor microarray chip and instrumentation with application to serotyping ofEscherichia coliisolates

Sensitive, fast-responding passive electrostatic radon monitor

Silicon photonic wire biosensors: Sensing, instrumentation, and applications

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