Patent application number | Description | Published |
20090015906 | EXTRINSIC GAIN LASER AND OPTICAL AMPLIFICATION DEVICE - An optical amplifier on a silicon platform includes a first doped device layer and a second doped device layer. A gain medium is positioned between the first and second doped device layers. The gain medium comprises extrinsic gain materials so as to substantially confine in the gain medium a light signal and allow the optical amplifier to be electrically or optically pumped. | 01-15-2009 |
20090093074 | Light Emission From Silicon-Based Nanocrystals By Sequential Thermal Annealing Approaches - A method for enhancing photoluminescence includes providing a film disposed over a substrate, the film including at least one of a semiconductor and a dielectric material. Light emission may be activated by thermal annealing post growth treatments when thin film layers of SiO | 04-09-2009 |
20090195879 | DETERMINISTIC APERIODIC PATTERNED DIELECTRIC AND PLASMONIC MATERIALS FOR LOCALIZED ELECTROMAGNETIC FIELD ENHANCEMENT - A method is shown for the extension in higher spatial dimensions of deterministic, aperiodic structures which exhibit strong aperiodic effects and have overall compatibility with the planar technology of integrated optical circuits. Disclosed devices are operative in response to incident electromagnetic energy to create a distribution of electromagnetic energy having localized electromagnetic field enhancement, wherein the device includes a dielectric or plasmonic material having a region of interaction with the incident electromagnetic energy. The region of interaction has a deterministic, aperiodic patterning with an array of individual patterning elements of distinct refractive indices such that a variation of refractive index of the device occurs over distances comparable with a wavelength of the incident electromagnetic energy, the array being a multi-dimensional extension of a corresponding one-dimensional sequence such that a spectral response of the array is a multi-dimensional equivalent of a spectral response of the one-dimensional sequence. Specific examples employing so-called Rudin-Shapiro, Thue-Morse and Fibonacci sequences are shown. | 08-06-2009 |
20100091358 | EXTRINSIC GAIN LASER AND OPTICAL AMPLIFICATION DEVICE - An optical amplifier on a silicon platform includes a first doped device layer and a second doped device layer. A gain medium is positioned between the first and second doped device layers. The gain medium comprises extrinsic gain materials so as to substantially confine in the gain medium a light signal and allow the optical amplifier to be electrically or optically pumped. | 04-15-2010 |
20110267614 | ENGINEERED SERS SUBSTRATES EMPLOYING NANOPARTICLE CLUSTER ARRAYS WITH MULTISCALE SIGNAL ENHANCEMENT - Defined nanoparticle cluster arrays (NCAs) with total lateral dimensions of up to 25.4 μm by 25.4 μm have been fabricated on top of a 10 nm thin gold film using template guided self-assembly. This approach provides precise control of the structural parameters in the arrays allowing a systematic variation of the average number of nanoparticles in the clusters (n) and the edge to edge separation (Λ) between 111-03-2011 | |
20110285991 | CHEMICAL/BIOLOGICAL SENSOR EMPLOYING SCATTERED CHROMATIC COMPONENTS IN NANO-PATTERNED APERIODIC SURFACES - A label-free multiplexed sensing platform is based on light interaction with aperiodic photonic structures with an advantage of a broadband operation. Multiple-scattering-induced “fingerprinting” colorimetric signatures can be used as a transduction mechanism. Aperiodic sensing platforms can operate in the infrared to provide an overlap with spectral fingerprints of biological molecules. Miniaturized optical biosensors may be based on engineered colorimetric scattering signatures (structural color), sharp spectral features, non-uniform angular distributions of scattered light, and broadband manipulation of the local density of states in nano-textured scattering surfaces with deterministic aperiodic order. The biosensors can be fabricated in semiconductor, metal, low- and high-index dielectric platforms using standard nanofabrication techniques such as electron-beam lithography, ion-beam milling, etc, and can be replicated over large areas by standard nano-imprint lithography. | 11-24-2011 |
20120121820 | FABRICATION OF SILK FIBROIN PHOTONIC STRUCTURES BY NANOCONTACT IMPRINTING - A method of manufacturing a nanopatterned biophotonic structure includes forming a customized nanopattern mask on a substrate using E-beam lithography, providing a biopolymer matrix solution, depositing the biopolymer matrix solution on the substrate, and drying the biopolymer matrix solution to form a solidified biopolymer film. A surface of the film is formed with the nanopattern mask, or a nanopattern is machined directly on a surface of the film using E-beam lithograpy such that the biopolymer film exhibits a spectral signature corresponding to the E-beam lithograpy nanopattern. The resulting bio-compatible nanopatterned biophotonic structures may be made from silk, may be biodegradable, and may be bio-sensing devices. The biophotonic structures may employ nanopatterned masks based on non-periodic photonic lattices, and the biophotonic structures may be designed with specific spectral signatures for use in probing biological substances, including displaying optical activity in the form of opalescence. | 05-17-2012 |
20130330710 | SILK BASED BIOPHOTONIC SENSORS - The present disclosure relates to biophotonic sensors. An example of a biophotonic sensor may be an apparatus for analyzing a sample. The apparatus may include a substrate, aperiodic nanostructured protrusions disposed on the substrate, and a silk material deposited between the protrusions. | 12-12-2013 |
20140016181 | OPTICAL DEVICES WITH SPIRAL APERIODIC STRUCTURES FOR CIRCULARLY SYMMETRIC LIGHT SCATTERING - Optical devices including deterministic aperiodic patterning using spiral arrays exhibit circular symmetry in continuous Fourier space via polarization-insensitive planar diffraction. Far-field diffractive coupling in these structures leads to the formation of scattering resonances with circular symmetry and characteristic vortex behavior carrying orbital angular momentum. Plasmonic nanoparticle arrays with aperiodic spiral geometry can be used in fabrication of optical devices that benefit from polarization insensitive, enhanced light-matter coupling on planar surfaces, such as thin-film solar cells (enhanced light absorption and efficiency), photodetectors (enhanced light emission and efficiency), optical biosensors, and polarization devices. | 01-16-2014 |