Abstract: A directly bonded optical component comprising one or more optical channels is disclosed. The directly bonded optical component can include at least a first optical element and a second optical element directly bonded to the first optical element without an intervening adhesive. The optical component can include a first optical channel through at least a portion of the first optical element, the first optical channel extending between a first port at a first side of the optical component and a second port at a second side of the optical component. A second optical channel or waveguide can extend through at least a portion of the second optical element from a third port at the first side of the optical component to a fourth port. The first and third ports can be separated by a first distance and the second and fourth parts can be separated a second distance along an exterior surface of the optical component. The first distance can be different from the second distance.

Abstract: The present invention provides a sensor having, one or more optical slab waveguides having one or more target regions. The target regions may interact with gas molecules or trap, entrain or capture one or more targets of interest. The optical slab waveguides are adapted to receive one or more input optical beams from one or more light sources to create a plurality of propagating optical waves in optical slab waveguide. The propagating optical waves interact with said one or more target regions to create an optical output wavefront that may be in the form of a diffraction pattern. The target regions may be functionalized with an antibody, polymer, cell, tissue, or biological material.

Abstract: The present invention provides a sensor having, one or more optical slab waveguides having one or more target regions. The target regions may interact with gas molecules or trap, entrain or capture one or more targets of interest. The optical slab waveguides are adapted to receive one or more input optical beams from one or more light sources to create a plurality of propagating optical waves in optical slab waveguide. The propagating optical waves interact with said one or more target regions to create an optical output wavefront that may be in the form of a diffraction pattern. The target regions may be functionalized with an antibody, polymer, cell, tissue, or biological material.

Abstract: The present invention provides a sensor having, one or more optical slab waveguides having one or more target regions. The target regions may interact with gas molecules or trap, entrain or capture one or more targets of interest. The optical slab waveguides are adapted to receive one or more input optical beams from one or more light sources to create a plurality of propagating optical waves in optical slab waveguide. The propagating optical waves interact with said one or more target regions to create an optical output wavefront that may be in the form of a diffraction pattern. The target regions may be functionalized with an antibody, polymer, cell, tissue, or biological material.

Abstract: Provided is a sensor platform that includes a substrate, a plurality of nanochannels disposed on the substrate, and a plurality of electrodes, a waveguide disposed on the substrate and an analysis chamber and a reference chamber disposed on the substrate. Each electrode extends substantially across a width of the plurality of nanochannels. At least one analysis optical resonator is disposed in the analysis chamber and is optically coupled to at least a portion of the waveguide. The at least one analysis optical resonator is in fluid communication with at least one of the plurality of nanochannels. At least one reference optical resonator is disposed in the reference chamber and is optically coupled to at least a portion of the waveguide. The at least one reference optical resonator is in fluid communication with at least one other of the plurality of nanochannels.

Abstract: An optical microresonator based RF oscillator sensor for measuring mass, temperature, and particle/molecule concentration. An optical energy source is coupled to the optical microresonator to generate optical power oscillations at Rf frequencies. A stable or reference RF oscillation frequency is established which allows for measuring oscillation frequency variations induced by the interaction of the substance with the optical microresonator.

Abstract: The present invention concerns an optical molecular sensing device and related method. The optical molecular sensing device has an optical resonator adapted to be connected to an excitation source. The excitation source may be a laser operating at a 2.7-2.8 um spectral range. The optical molecular sensing device has an emission spectrum comprised of a plurality wavelengths. Also included are a detection unit and a RF frequency counter to detect at least one RF beat note resulting from detecting the emission spectrum of the optical resonator. A change in frequency of the RF beat note indicates the presence of a target molecule.

Abstract: A photonically controlled microwave device having a photosensitive substrate having an interior region comprising a high radio frequency (“RF”) field for a resonant RF mode. An RF resonator is patterned on a surface of the substrate, the pattern includes an aperture in the resonator positioned to direct light received from a light source to the interior region. The light source may have a wavelength that enables illumination of the interior region to generate free carriers or other photo-induced changes in RF permittivity. An optical boundary may be provided that recirculates the unabsorbed optical power inside the high RF field region until it is fully absorbed.

Abstract: An optical resonator made from an elongated fiber having a proximal and distal end. A sphere is created on the distal end by locating the distal end in cylindrically symmetrical heating zone along a centerline. For some embodiments, the distal end is rapidly cooled by allowing it to retract away from the heating zone along the centerline during the formation and solidification of the molten microsphere. The resulting optical resonator has an intrinsic quality factor greater than 106 over the 2.0 to 3.2 ?m MIR wavelength range.

Abstract: An all optical radio frequency converter. The invention relates to a microtoroid optomechanical oscillator that can provide a local oscillation frequency and a mixing functionality. The microtoroid optomechanical oscillator can be fabricated from a silica-on-silicon wafer. When an input optical signal having an optical carrier frequency carrying a modulated RF signal representing information is applied to the microtoroid optomechanical oscillator, a signal including the baseband information modulated on the optical carrier is provided as output. The output signal can be detected with a photodetector. Information carried by the optical signal can be recorded and/or displayed to a user. Injection locking of the microtoroid optomechanical oscillator can be accomplished by providing a signal of suitable frequency. The frequency and the phase of operation of the microtoroid optomechanical oscillator can be locked to the respective frequency and phase of the injected locking signal.

Abstract: Provided is a sensor platform that includes a substrate, a plurality of nanochannels disposed on the substrate, and a plurality of electrodes, a waveguide disposed on the substrate and an analysis chamber and a reference chamber disposed on the substrate. Each electrode extends substantially across a width of the plurality of nanochannels. At least one analysis optical resonator is disposed in the analysis chamber and is optically coupled to at least a portion of the waveguide. The at least one analysis optical resonator is in fluid communication with at least one of the plurality of nanochannels. At least one reference optical resonator is disposed in the reference chamber and is optically coupled to at least a portion of the waveguide. The at least one reference optical resonator is in fluid communication with at least one other of the plurality of nanochannels.

Abstract: An optical resonator made from an elongated fiber having a proximal and distal end. A sphere is created on the distal end by locating the distal end in cylindrically symmetrical heating zone along a centerline. For some embodiments, the distal end is rapidly cooled by allowing it to retract away from the heating zone along the centerline during the formation and solidification of the molten microsphere. The resulting optical resonator has an intrinsic quality factor greater than 106 over the 2.0 to 3.2 ?m MIR wavelength range.

Abstract: An optical microresonator based RF oscillator sensor for measuring mass, temperature, and particle/molecule concentration. An optical energy source is coupled to the optical microresonator to generate optical power oscillations at Rf frequencies. A stable or reference RF oscillation frequency is established which allows for measuring oscillation frequency variations induced by the interaction of the substance with the optical microresonator.

Abstract: A method of fabricating a microresonator is disclosed. Initially, silica is deposited on a substrate, and the substrate is etched to form a pillar, the top portion of which supports the silica. The microresonator is then formed from the silica. Next, the pillar is etched to reduce the overall diameter of the top portion of the pillar so that the microresonator can be disengaged from the pillar.

Abstract: An all optical radio frequency converter. The invention relates to a microtoroid optomechanical oscillator that can provide a local oscillation frequency and a mixing functionality. The microtoroid optomechanical oscillator can be fabricated from a silica-on-silicon wafer. When an input optical signal having an optical carrier frequency carrying a modulated RF signal representing information is applied to the microtoroid optomechanical oscillator, a signal including the baseband information modulated on the optical carrier is provided as output. The output signal can be detected with a photodetector. Information carried by the optical signal can be recorded and/or displayed to a user. Injection locking of the microtoroid optomechanical oscillator can be accomplished by providing a signal of suitable frequency. The frequency and the phase of operation of the microtoroid optomechanical oscillator can be locked to the respective frequency and phase of the injected locking signal.

Abstract: A method of fabricating a microresonator is disclosed. Initially, silica is deposited on a substrate, and the substrate is etched to form a pillar, the top portion of which supports the silica. The microresonator is then formed from the silica. Next, the pillar is etched to reduce the overall diameter of the top portion of the pillar so that the microresonator can be disengaged from the pillar.