Abstract: An optofluidic photobioreactor including an optical waveguide having an input, characterized by an evanescent optical field confined along an outer surface of the optical waveguide produced by radiation propagating in the optical waveguide, means for inputting light to the input of the optical waveguide, and a selected photosynthetic microorganism disposed substantially within the evanescent field. A method for optically exciting a photosynthetic microorganism for generating a biofuel, a biofuel precursor, or a biomass from the optically-excited photosynthetic microorganism involves irradiating the photosynthetic microorganism attached to the surface of the waveguide with an evanescent optical field from optical radiation propagating in the optical waveguide, and driving photosynthesis in the microorganism by the evanescent optical field.

Abstract: Fiber optic sensors include sensor regions in which an optical phase is modulated by an analyte to be detected. A long period fiber grating (LPG) is coupled to a coating that is arranged to selectively interact with the analyte. The resulting phase change is detected based on a transmission spectrum associated with the LPG so that analyte is detected and quantified. A plurality of such sensors is distributed along a fiber to form a sensor array that can be situated to detect analyte at a plurality of discrete regions.

Abstract: The present invention presents a device and methods of use thereof in combined electrohydrodynamic concentration and plasmonic detection of a charged species of interest using a flow-through nanohole array. The device comprises microchannels, which are linked to a substrate with arrays of through nanoholes, wherein the substrate comprises two layers, wherein one of the layers is made of insulator material and one of the layers is made of metal, whereby induction of an electric field across the nanohole array results in the species of interest concentrating inside the nanoholes and in the vicinity of the nanohole arrays. The induction of an electric field is achieved by means of an external electric field source, which is applied to the fluid containing the species of interest, resulting in electroosmotic (EO) flow. An additional pressure driven fluid flow in the microchannels, co-directional to the EO flow is applied by external means.

Abstract: An optofluidic photobioreactor including an optical waveguide having an input, characterized by an evanescent optical field confined along an outer surface of the optical waveguide produced by radiation propagating in the optical waveguide, means for inputting light to the input of the optical waveguide, and a selected photosynthetic microorganism disposed substantially within the evanescent field. A method for optically exciting a photosynthetic microorganism for generating a biofuel, a biofuel precursor, or a biomass from the optically-excited photosynthetic microorganism involves irradiating the photosynthetic microorganism attached to the surface of the waveguide with an evanescent optical field from optical radiation propagating in the optical waveguide, and driving photosynthesis in the microorganism by the evanescent optical field.

Abstract: The present invention presents a device and methods of use thereof in combined electrohydrodynamic concentration and plasmonic detection of a charged species of interest using a flow-through nanohole array. The device comprises microchannels, which are linked to a substrate with arrays of through nanoholes, wherein the substrate comprises two layers, wherein one of the layers is made of insulator material and one of the layers is made of metal, whereby induction of an electric field across the nanohole array results in the species of interest concentrating inside the nanoholes and in the vicinity of the nanohole arrays. The induction of an electric field is achieved by means of an external electric field source, which is applied to the fluid containing the species of interest, resulting in electroosmotic (EO) flow. An additional pressure driven fluid flow in the microchannels, co-directional to the EO flow is applied by external means.

Abstract: A microfluidic fuel cell with flow-through architecture is provided. The anode and the cathode are porous electrodes and comprise an interstitial pore network. A virtual insulator is located between the electrodes, in an electrolyte channel. The virtual insulator is comprised of a co-laminar flow of an electrolyte. An inlet directs substantially all the flow of liquid reactant through the porous electrode.