Abstract: Embodiments described herein relate to providing authenticated access to passenger-specific information at a seatback device of a vehicle based on connection with personal passenger devices. A method includes obtaining a unique identifier associated with a passenger device that is wirelessly connected with a seatback device located in a vehicle. The method includes determining whether an account data for a passenger corresponding to the seatback device includes an indication of the unique identifier. The method includes automatically causing, based on a determination that the account data includes the indication of the unique identifier associated with the passenger device, at least a portion of the account data to be displayed at the seatback device.

Abstract: Disclosed is a modular bio-processing unit comprising: a housing having one or more internal fluid paths, the housing having at least one inlet and at least one outlet, each in fluid communication with the fluid path or one or more of the fluid paths; one or more sensor elements operatively associated with the or each path, said sensor(s) elements including elements of one or more of: a flow sensor, a flow rate sensor, a conductivity sensor, a pressure sensor, a pH sensor, and a light absorbance sensor such as a UV spectroscopic concentration sensor; one or more fluid flow inducing components operatively associated with the or each fluid path; and plural valves for preventing or reducing flow in the or each path, the housing, inlet(s), outlet(s), flow inducing component(s) and valve(s) being arranged to operate together as a bio-processing unit within or substantially within the housing.

Abstract: A system and method for removing and destroying PFAS from residual waste streams generated during the processing of landfill liquids prior to disposal are provided. The presently disclosed system and method can concentrate PFAS from landfill liquids into a residual waste stream so that the target compounds can be selectively removed for subsequent destruction.

Abstract: A tunable optical filter comprises a resonant grating layer having an aperiodic pattern, an optional sublayer, a waveguide layer, and a substrate layer, wherein at least one of the waveguide layer and the sublayer, when present is inhomogenous. In some instances, the optional sublayer and/or the waveguide layer may comprise a thickness gradient. Incident light may be filtered and/or reflected by an optical filter, for instance a band of incident electromagnetic radiation has 90% or greater transmittance or reflectance and adjacent bands of incident electromagnetic radiation have 10% or less transmittance or reflectance, respectively.

Abstract: The invention disclosed herein generally relates to wideband resonant polarizers that require extremely small amounts of matter in their embodiments. These polarizers can be made with dielectric materials such that light and other electromagnetic waves interacting with them suffer essentially no absorptive loss. This new class of polarizers is fashioned with dielectric or semiconductor nano/microwire grids that are mostly empty space if surrounded by air or vacuum. It is fundamentally and practically extremely significant that the wideband spectral expressions presented herein can be generated in these minimal systems. These ultra-sparse polarizers are useful in various spectral regions for numerous useful applications.

Abstract: A method of fabricating a metasurface comprises coating a photoresist film onto a substrate and loading the coated substrate into a laser interference lithography setup, exposing the photoresist film via a laser with a first interference pattern, the first interference pattern having a first period and a first exposure energy, subsequently exposing the coated substrate with a second interference pattern, the second interference pattern having a second period and a second exposure energy, developing the exposed portions of the photoresist film to form a periodic pattern in the photoresist, and transferring the periodic pattern into the substrate, the substrate supporting an appropriate film system that embodies the final metasurface device.

Abstract: Unpolarized broadband reflectors enabled by a serial arrangement of a pair of polarized subwavelength gratings are disclosed. Device illustrations include partially-etched crystalline-silicon films on quartz substrates and amorphous silicon films on glass. The individual reflectors exhibit extremely wide spectral reflection bands in one polarization. By arranging two such reflectors sequentially with orthogonal periodicities, there results an unpolarized spectral band that exceeds those of the individual polarized bands. In the prototypes disclosed, there results zero-order reflectance exceeding 97% under unpolarized light incidence over a 500-nm-wide wavelength band. This wideband represents a ˜44% fractional band in the near infrared spectral band. The elemental polarization-sensitive reflectors based on one-dimensional resonant gratings have simple design, robust performance, and are straightforward to fabricate.

Abstract: Disclosed is a new class of wideband reflectors that are relatively insensitive to deviations from the design parameters. The reflectors are materially sparse while providing high reflectance across wide spectral bands. In some embodiments, a device comprises a substrate and a grating layer disposed on the substrate, wherein the grating layer comprises a periodic grating structure and a sublayer beneath the grating structure and adjacent to the substrate, the grating layer and the sublayer having the same index of refraction. These compact, low-loss elements complement conventional thin-film reflectors while possessing properties not available in thin-film multilayer stacks. The reflectors are based on a fundamental resonance effect, the guided-mode resonance effect, that occurs in periodic structures. Disclosed herein are both one-dimensional and two-dimensional reflectors m zero-contrast embodiments.

Abstract: Narrow bandpass filters are useful in numerous practical applications including laser systems, imaging, telecommunications, and astronomy. Traditionally implemented with thin-film stacks, there exists alternate means incorporating photonic resonance effects. Accordingly, here we disclose a new approach to bandpass filters that engages the guided-mode resonance effect working in conjunction with a cavity-based Fabry-Pérot resonance to flatten and steepen the pass band. Both of these resonance mechanisms are native to simple resonant bandpass filters placed in a cascade. To support the disclosure, numerical examples provide quantitative spectral characteristics including pass-band shape and sideband levels. Thus, we compare the spectra of single-layer 1D- and 2D-patterned resonant gratings with a dual-grating cascade design incorporating mathematically identical gratings. Dual and triple cascade designs are measured against a classic multi-cavity thin-film filter with 151 layers.

Abstract: The invention disclosed herein generally relates to wideband resonant polarizers that require extremely small amounts of matter in their embodiments. These polarizers can be made with dielectric materials such that light and other electromagnetic waves interacting with them suffer essentially no absorptive loss. This new class of polarizers is fashioned with dielectric or semiconductor nano/microwire grids that are mostly empty space if surrounded by air or vacuum. It is fundamentally and practically extremely significant that the wideband spectral expressions presented herein can be generated in these minimal systems. These ultra-sparse polarizers are useful in various spectral regions for numerous useful applications.

Abstract: The invention disclosed herein generally relates to wideband resonant polarizers that require extremely small amounts of matter in their embodiments. These polarizers can be made with dielectric materials such that light and other electromagnetic waves interacting with them suffer essentially no absorptive loss. This new class of polarizers is fashioned with dielectric or semiconductor nano/microwire grids that are mostly empty space if surrounded by air or vacuum. It is fundamentally and practically extremely significant that the wideband spectral expressions presented herein can be generated in these minimal systems. These ultra-sparse polarizers are useful in various spectral regions for numerous useful applications.

Abstract: Disclosed is a modular bio-processing unit (100) comprising: a housing (110) having one or more internal fluid paths (101), the housing having at least one inlet and at least one outlet (5,10,15,20,25,30,35,40,45,50,55,60,65,70), each in fluid communication with the fluid path or one or more of the fluid paths; one or more sensor elements (120,150,170,190) operatively associated with the or each path, said sensor(s) elements including elements of one or more of: a flow sensor, a flow rate sensor, a conductivity sensor, a pressure sensor, a pH sensor, and a light absorbance sensor such as a UV spectroscopic concentration sensor; one or more fluid flow inducing components (140) operatively associated with the or each fluid path; and plural valves (180) for preventing or reducing flow in the or each path, the housing, inlet(s), outlet(s), flow inducing component(s) and valve(s) being arranged to operate together as a bio-processing unit within or substantially within the housing.

Abstract: Multilevel leaky-mode optical elements, including reflectors, polarizers, and beamsplitters. Some of the elements have a plurality of spatially modulated periodic layers coupled to a substrate. For infrared applications, the optical elements may have a bandwidth larger than 600 nanometers.

Abstract: Waveguide gratings, biosensors, and methods of using a waveguide grating, including as a biosensor.

Abstract: A guided mode resonance (GMR) sensor assembly and system are provided. The GMR sensor includes a waveguide structure configured for operation at or near one or more leaky modes, a receiver for input light from a source of light onto the waveguide structure to cause one or more leaky TE and TM resonant modes and a detector for changes in one or more of the phase, waveshape and/or magnitude of each of a TE resonance and a TM resonance to permit distinguishing between first and second physical states of said waveguide structure or its immediate environment.

Abstract: A spectroscopic device is disclosed. The spectroscopic device can include a beam collimation structure with a white light source. The beam collimation structure can also include a lens configured to generate a collimated light beam. The spectroscopic device can also include a polarization modulation structure. The polarization modulation structure can convert the collimated light beam into a common path light beam. The common path light beam can include a delayed component and a polarized component. The spectroscopic device can include a dual spectrum sensing structure. The dual spectrum sensing structure can sense a normalized spectral Stokes vector in real time speed.

Abstract: Multilevel leaky-mode optical elements, including reflectors, polarizers, and beamsplitters. Some of the elements have a plurality of spatially modulated periodic layers coupled to a substrate. For infrared applications, the optical elements may have a bandwidth larger than 600 nanometers.

Abstract: Multilevel leaky-mode optical elements, including reflectors, polarizers, and beamsplitters. Some of the elements have a plurality of spatially modulated periodic layers coupled to a substrate. For infrared applications, the optical elements may have a bandwidth larger than 600 nanometers.

Abstract: There is immense scientific interest in the properties of resonant thin films embroidered with periodic nanoscale features. This device class possesses considerable innovation potential. Accordingly, we report unpolarized broadband reflectors enabled by a serial arrangement of a pair of polarized subwavelength gratings. Optimized with numerical methods, the elemental gratings can be fabricated in various materials systems. Illustrative examples provided consist of a partially-etched crystalline-silicon films on a quartz substrate and amorphous silicon films on glass. The resulting reflectors exhibit extremely wide spectral reflection bands in one polarization. By arranging two such reflectors sequentially with orthogonal there results an unpolarized spectral band that exceeds those of the individual polarized bands. In the prototypes disclosed herein, there results zero-order reflectance exceeding 97% under unpolarized light incidence over a 500-nm-wide wavelength band.

Abstract: A guided mode resonance (GMR) sensor assembly and system are provided. The GMR sensor includes a waveguide structure configured for operation at or near one or more leaky modes, a receiver for input light from a source of light onto the waveguide structure to cause one or more leaky TE and TM resonant modes and a detector for changes in one or more of the phase, waveshape and/or magnitude of each of a TE resonance and a TM resonance to permit distinguishing between first and second physical states of said waveguide structure or its immediate environment.