Abstract: An apparatus for performing surface enhanced Raman spectroscopy includes an optical waveguide, a plurality of flexible nano-structures, wherein the plurality of nano-structures have respective free ends positioned within an evanescent field to be generated by light propagated through the optical waveguide, wherein the plurality of nano-structures are movable from a first position and a second position, wherein in the first position, the free ends of the plurality of nano-structures are substantially spaced from each other and in the second position, the free ends of a plurality of the nano-structures are substantially in contact with each other.

Abstract: An apparatus for performing spectroscopy includes a substrate, a photodetector positioned at a distance with respect to the substrate, and a plurality of sub-wavelength grating (SWG) filters positioned between the substrate and the photodetector, in which the SWG filters are to filter different ranges of predetermined wavelengths of light emitted from an excitation location prior to being emitted onto the photodetector.

Abstract: In one embodiment, an optical system includes a microfluidic chip assembly. The microfluidic chip assembly includes a first structure that provides a first wall of a fluid channel. A second structure provides a second wall of the fluid channel. The second structure includes a diffraction grating configured to provide, in the presence of incident light of a wavelength band of interest on a first surface of the second structure, a plurality of regions of high intensity light within the fluid channel.

Abstract: The present disclosure provides optical waveguide coupling devices and associated methods. In one example, an optical waveguide coupling device can comprise a dielectric grating coupler, a first optical waveguide attached to a first surface of the dielectric grating coupler, and a second optical waveguide attached to a second surface of the dielectric grating coupler. The second optical waveguide can be oriented opposed to the first optical waveguide allowing for communication therebetween via the sub-wavelength grating. Additionally, the dielectric grating coupler can comprise a first dielectric material; a sub-wavelength grating attached to the first dielectric material, the sub-wavelength grating having a higher refractive index than the first dielectric material; and a second dielectric material optically coupled to the sub-wavelength grating.

Abstract: Various embodiments of the present invention are directed to optical fiber coupling systems and to methods for fabricating optical fiber coupling systems. In one aspect, an optical fiber coupling system includes a first resonant cavity abutting the end of an optical fiber. The optical fiber coupling system includes a second resonant cavity located adjacent to the first cavity. The first and second resonant cavities are separated by a sub-wavelength grating layer configured with a non-periodic sub-wavelength grating. The optical fiber coupling system selectively couples light into and/or out of the optical fiber core.

Abstract: An apparatus for performing surface enhanced Raman spectroscopy includes an optical waveguide, a plurality of flexible nano-structures, wherein the plurality of nano-structures have respective free ends positioned within an evanescent field to be generated by light propagated through the optical waveguide, wherein the plurality of nano-structures are movable from a first position and a second position, wherein in the first position, the free ends of the plurality of nano-structures are substantially spaced from each other and in the second position, the free ends of a plurality of the nano-structures are substantially in contact with each other.

Abstract: A nanofinger device with magnetizable portion. The nanofinger device includes a substrate, and a plurality of nanofingers coupled with the substrate. A nanofinger of the plurality includes a flexible column, and at least one magnetizable portion. At least the nanofinger and a second nanofinger of the plurality of nanofingers are to arrange into a close-packed configuration. The magnetizable portion is to actuate the nanofinger in opening from the close-packed configuration in response to a physical stimulus affecting the magnetic state of the magnetizable portion. A chemical-analysis apparatus including the nanofinger device for chemical sensing and a method of using the nanofinger device for chemical sensing are also provided.

Abstract: An optically integrated magnetic biosensor includes an optically detected magnetic resonance (ODMR) center and a fluidics layer configured to contain a solution comprising analytes, the fluidics layer being disposed over the ODMR center. A light source which generates incident light excites electrons within the ODMR center from a ground state to an excited state and a radio frequency (RF) antenna generates an RF field incident with frequencies which correspond to ground state transitions in the ODMR center. The ODMR center produces emitted light when illuminated by the incident light. The characteristics of the emitted light are influenced by the RF field and magnetic nanoparticles attached to the analytes. A method for detecting analytes using optically detected magnetic resonance is also provided.

Abstract: A magnetometer includes a tapered microfiber having a curved portion, an excitation laser in optical communication with the tapered microfiber, and a nanocrystal attached to the curved portion of the tapered microfiber. Laser light emitted from the excitation laser interacts with the nanocrystal to create an emitted photon flux which is monitored to detect a magnetic field passing through the nanocrystal.

Abstract: Disclosed herein are optically and electrically actuatable devices. The optically and electrically actuatable device includes an insulating substrate, two electrodes, an active region, and a concentrator. At least one of the two electrodes is established on the insulating substrate, and another of the two electrodes is established a spaced distance vertically or laterally from the at least one of the two electrodes. The other of the two electrodes is an optical input electrode. The active region is established between or beneath the two electrodes. The concentrator is optically coupled to the optical input electrode for concentrating incident light such that a predetermined portion of the active region is optically actuatable.

Abstract: The present disclosure provides optical waveguide coupling devices and associated methods. In one example, an optical waveguide coupling device can comprise a dielectric grating coupler, a first optical waveguide attached to a first surface of the dielectric grating coupler, and a second optical waveguide attached to a second surface of the dielectric grating coupler. The second optical waveguide can be oriented opposed to the first optical waveguide allowing for communication therebetween via the sub-wavelength grating. Additionally, the dielectric grating coupler can comprise a first dielectric material; a sub-wavelength grating attached to the first dielectric material, the sub-wavelength grating having a higher refractive index than the first dielectric material; and a second dielectric material optically coupled to the sub-wavelength grating.

Abstract: A sensor apparatus, a sensor system and a method employ coupling characterization of a sensor housing to a local environment. The apparatus includes a vibration sensor and a vibration actuator attached to and enclosed by the sensor housing in a spaced apart relationship. The vibration actuator is configured to vibrate the sensor housing with a vibration signal to excite a coupling between the sensor housing and the local environment. A response of the sensor housing to the vibration signal is indicative of a coupling characteristic of the coupling. The system further includes a coupling structure. The method includes coupling the sensor housing to the local environment, vibrating the sensor housing with the vibration actuator and detecting the response that is indicative of the coupling characteristic.

Abstract: Various embodiments of the present invention are directed to optical fiber coupling systems and to methods for fabricating optical fiber coupling systems. In one aspect, an optical fiber coupling system includes a first resonant cavity abutting the end of an optical fiber. The optical fiber coupling system includes a second resonant cavity located adjacent to the first cavity. The first and second resonant cavities are separated by a sub-wavelength grating layer configured with a non-periodic sub-wavelength grating. The optical fiber coupling system selectively couples light into and/or out of the optical fiber core.

Abstract: An optically integrated magnetic biosensor includes an optically detected magnetic resonance (ODMR) center and a fluidics layer configured to contain a solution comprising analytes, the fluidics layer being disposed over the ODMR center. A light source which generates incident light excites electrons within the ODMR center from a ground state to an excited state and a radio frequency (RF) antenna generates an RF field incident with frequencies which correspond to ground state transitions in the ODMR center. The ODMR center produces emitted light when illuminated by the incident light. The characteristics of the emitted light are influenced by the RF field and magnetic nanoparticles attached to the analytes. A method for detecting analytes using optically detected magnetic resonance is also provided.

Abstract: Disclosed herein are optically and electrically actuatable devices. The optically and electrically actuatable device includes an insulating substrate, two electrodes, an active region, and a concentrator. At least one of the two electrodes is established on the insulating substrate, and another of the two electrodes is established a spaced distance vertically or laterally from the at least one of the two electrodes. The other of the two electrodes is an optical input electrode. The active region is established between or beneath the two electrodes. The concentrator is optically coupled to the optical input electrode for concentrating incident light such that a predetermined portion of the active region is optically actuatable.

Abstract: A magnetometer includes a tapered microfiber having a curved portion, an excitation laser in optical communication with the tapered microfiber, and a nanocrystal attached to the curved portion of the tapered microfiber. Laser light emitted from the excitation laser interacts with the nanocrystal to create an emitted photon flux which is monitored to detect a magnetic field passing through the nanocrystal.