Abstract: An electronic combination lock comprising a rotatable dial, an energy-harvesting device operatively connected to and configured to harvest energy from the rotatable dial, an energy-storage device operatively connected to and configured to be powered by the energy-harvesting device, a security status indicator operatively connected to and configured to by powered by the energy storage device, and logic configured to determine whether the combination lock is in a secure state and to activate the security-status indicator when the electronic combination lock is not in a secure state. A security-indication device for use with a combination device. A method for indicating a combination lock is not in a secure state comprising the steps of harvesting energy, storing the harvested energy, determining whether the combination lock is in a secure state, and, upon determining the combination lock is not in a secure state, activating a security-status indicator by powering it with stored energy.

Abstract: A waveguide and methods for manufacture can include a silicon wafer and a silicon substrate on the wafer that can be patterned into a silicon waveguide. A cladding can be deposited on the wafer and that waveguide using a plasma enhanced chemical vapor deposition (PECVD) process. When a PECVD process is used, the cladding portions that are in contact with that waveguide and in the immediate vicinity can have a lower density, and a lower refractive index n of less than (n<1.3). The lower uniform cladding refractive index can be uniform from the waveguide surfaces out to approximately one micrometer from the waveguide. This can further in result in an increased difference between the refractive index of the silicon waveguide and the adjacent lower refractive index cladding portions, which can further result in greater light confinement within the waveguide (i.e. reduced losses during transmission).

Abstract: A waveguide and methods for manufacture can include a silicon wafer and a silicon substrate on the wafer that can be patterned into a silicon waveguide. A cladding can be deposited on the wafer and that waveguide using a plasma enhanced chemical vapor deposition (PECVD) process. When a PECVD process is used, the cladding portions that are in contact with that waveguide and in the immediate vicinity can have a lower density, and a lower refractive index n of less than (n<1.3). The lower uniform cladding refractive index can be uniform from the waveguide surfaces out to approximately one micrometer from the waveguide. This can further in result in an increased difference between the refractive index of the silicon waveguide and the adjacent lower refractive index cladding portions, which can further result in greater light confinement within the waveguide (i.e. reduced losses during transmission).

Abstract: A system for detecting tampering. The system comprises a first luminescent layer adjacent to a first item of value and an optical detector operably connected to an alarm. The first luminescent layer emits a light beam, which is detected by the optical detector. Upon detection of the light beam, the optical detector activates the alarm.

Abstract: A method is provided for creating a chamber on a semiconductor substrate, utilizing wet etching or dry etching, back-filling the chamber with a polymeric compound, and sealing the chamber.

Abstract: A tunable ultra-compact spectrometer and methods for spectrometry therefor can include a single pixel and a Fresnel zone plate having a focal length at a first temperature T1 and a first wavelength ?1, and a focal point. The pixel can be twenty micrometers square and can be placed at a distance from the pixel that equal to the focal length so that the focal point is at the pixel. The Fresnel zone plate can be made of a material that causes the same focal point at the pixel at T2, but at a different wavelength ?2 than wavelength ?1. A heat source can selectively add heat to the Fresnel zone plate to cause a second temperature T2. Exemplary materials for the Fresnel zone plate can be quartz for visible wavelengths, silicon for infrared wavelength, or other materials, according to the ?(s) of interest.

Abstract: Photonic devices may include a first ring resonator and a second ring resonator located within the first ring resonator, the second ring resonator separated from and optically coupled to the first ring resonator. A waveguide structure is optically coupled to the first ring resonator and may be parallel bus waveguides optically coupled on opposite ends of the first ring resonator or a u-shaped waveguide wrapped substantially around the first ring resonator. A third ring resonator may located within the second ring resonator and may be separated from and optically coupled to the first ring resonator and the second ring resonator. A sensing medium may be disposed within the interior of the third ring resonator and optically coupled to the third ring resonator. The sensing medium is configured to undergo a change in refractive index responsive to one or more analytes bound to the sensing medium.

Abstract: A system for stabilizing the temperature sensitivity in photonic circuits comprising a thermoelastic cladding directly overlaid on a photonic circuit, wherein the properties of the thermoelastic cladding are such that the temperature of the photonic circuit is passively stabilized, such as by adjustment of the effective refractive index of the photonic circuit. The thermoelastic cladding may comprise a negative thermo-optic coefficient and the photonic circuit has a positive thermo-elastic coefficient. The thermoelastic cladding may be a liquid, solid, or gas, and may be contained within a chamber having an inlet and an outlet. A pressure sensor may be contained within the chamber for monitoring pressure. The sensor can detect whether the fluid/gas has reached its maximum expansion and can send a signal when that happens. The pressure sensor is connected in a feedback loop and it sends an alarm once the chamber pressure is at a maximum.

Abstract: Photonic devices may include a first ring resonator and a second ring resonator located within the first ring resonator, the second ring resonator separated from and optically coupled to the first ring resonator. A waveguide structure is optically coupled to the first ring resonator and may be parallel bus waveguides optically coupled on opposite ends of the first ring resonator or a u-shaped waveguide wrapped substantially around the first ring resonator. A third ring resonator may located within the second ring resonator and may be separated from and optically coupled to the first ring resonator and the second ring resonator. A sensing medium may be disposed within the interior of the third ring resonator and optically coupled to the third ring resonator. The sensing medium is configured to undergo a change in refractive index responsive to one or more analytes bound to the sensing medium.

Abstract: A system for stabilizing the temperature sensitivity in photonic circuits comprising a thermoelastic cladding directly overlaid on a photonic circuit, wherein the properties of the thermoelastic cladding are such that the temperature of the photonic circuit is passively stabilized, such as by adjustment of the effective refractive index of the photonic circuit. The thermoelastic cladding may comprise a negative thermo-optic coefficient and the photonic circuit has a positive thermo-elastic coefficient. The thermoelastic cladding may be a liquid, solid, or gas, and may be contained within a chamber having an inlet and an outlet. A pressure sensor may be contained within the chamber for monitoring pressure. The sensor can detect whether the fluid/gas has reached its maximum expansion and can send a signal when that happens. The pressure sensor is connected in a feedback loop and it sends an alarm once the chamber pressure is at a maximum.

Abstract: In a cyphertext (CT) network, a method for detecting anomalies comprising analyzing cyphertext data flows within the CT network where the CT network includes one or more encryption devices for encrypting plaintext data packets into cyphertext data packets such that the cyphertext data flows are directed to one or more destination devices. The cyphertext data includes multiple CT data packets and each CT data packet includes header information where each header includes source address information, destination address information and differentiated service code point (DSCP) information representative of traffic class information. The method further includes analyzing the traffic class information of each header, including using maximum entropy estimation for detecting one or more anomalies within the traffic class distribution of each flow based on the header information for that traffic class.

Abstract: A temperature-stabilized photonic circuit comprising: a material platform; a complementary metal-oxide-semiconductor (CMOS)-compatible, photonic device integrated on the material platform, wherein the photonic device has a positive thermo-optic coefficient; and a liquid crystal layer clad over the photonic device, wherein the liquid crystal layer has a negative thermo-optic coefficient such that the temperature of the circuit is passively stabilized through adjustment of the effective refractive index of the photonic device.

Abstract: A temperature-stabilized photonic circuit comprising: a material platform; a complementary metal-oxide-semiconductor (CMOS)-compatible, photonic device integrated on the material platform, wherein the photonic device has a positive thermo-optic coefficient; and a liquid crystal layer clad over the photonic device, wherein the liquid crystal layer has a negative thermo-optic coefficient such that the temperature of the circuit is passively stabilized through adjustment of the effective refractive index of the photonic device.

Abstract: A differential measurement design employing two nearly collinear optical beams provides surface plasmon polariton resonance (SPR) sensors and a corresponding method of increased dynamic range and signal to noise ratio. The differential measurement device and method based on wavelength interrogation, employs a single incident polarization state, and is combined with a 2-D nanohole array for operation at near-normal incidence, where this approach offers a decrease in the measurement time.

Abstract: A differential measurement design employing two nearly collinear optical beams provides surface plasmon polariton resonance (SPR) sensors and a corresponding method of increased dynamic range and signal to noise ratio. The differential measurement device and method based on wavelength interrogation, employs a single incident polarization state, and is combined with a 2-D nanohole array for operation at near-normal incidence, where this approach offers a decrease in the measurement time.

Abstract: A system includes a substrate having a plurality of three-dimensional photonic crystal elements directly coupled thereto. The photonic crystal elements may each partially or substantially coated with oriented graphene and may comprise undoped silicon. The graphene may be oriented in a direction parallel to or normal to the photonic crystal element and may comprise graphene flakes contained within a composite thin film. The system may also include at least one optical component, such as a waveguide, contained within the plurality of three-dimensional photonic crystal elements. A method is also provided for preparing the graphene and coating the photonic crystal elements with the graphene.

Abstract: An optical-powered device includes a flexible substrate, a photonic bandgap layer coupled thereto, a waveguide contained within the photonic bandgap layer, and a dendrimer region contained within the waveguide. The dendrimer region may comprise more than one dendrimers. The dendrimer region emission band is within the photonic bandgap of the photonic bandgap layer. Multiple photonic bandgap layers may be included, with one or more waveguides therein. Each waveguide may have a dendrimer region therein. Electronic circuitry may be contained within a portion of the photonic bandgap layer. A light-modulating layer may be directly coupled to the photonic bandgap layer. A portion of the photonic bandgap layer may have a sensing material embedded therein. A cover layer having one or more windows may be coupled to the photonic bandgap layer. Another layer, such as a buffer layer, may be disposed between the substrate layer and the photonic bandgap layer.

Abstract: A plasmonic transistor device includes an electro-optic substrate and a conductive layer placed on said electro-optic substrate to establish an interface therebetween. The first conductive layer and electro-optics substrate are made of materials that are suitable for transmission of a surface plasmon along the interface. The conductive layer is further formed with a source input grating and a drain output grating, for establishing the surface plasmon. A means for varying the electro-optic substrate permittivity, such as a light source or voltage source, is connected to the electro-optic substrate. Selective manipulation of the varying means allows the user to selectively increase or decrease the substrate permittivity. Control of the substrate permittivity further allows the user to control surface plasmon propagation from the source input grating along the interface to a drain output grating, to achieve a transistor-like effect for the surface plasmon.

Abstract: A plasmonic logic device can include a dielectric substrate, and first and second metallic input strips that are placed on the substrate. The input metallic strips can be made of different metals that support propagation of surface plasmons at different frequencies. The input metallic strips can be separated by a predetermined gap that causes for the surface plasmons to constructively combine or destructively cancel each other, according to the gap distances and strip materials chosen, to accomplish the desired logic function. A metallic output strip can be placed on the substrate at a distance from the metallic input strips that allows for selective propagation to accomplish different logic functions. The metallic output strip can further be chosen from a material that allows for propagation of surface plasmons over a broad frequency range to allow for evanescent coupling of a surface plasmon from the metallic input strips.

Abstract: A plasmonic router can include a first surface plasmon guide and a second surface plasmon guide. A surface plasmon can be generated in either of the plasmon guides. Each plasmon guide has an energy barrier, which can be selectively decreased to allow selective propagation of the generated surface plasmon through the plasmon guide. The generated surface plasmon has an evanescent wave that extends outwardly from the plasmon guide by a spatial extent. To allow for surface plasmon propagation between plasmon guides, the plasmon guides can be spaced apart by a predetermined gap that is less than the spatial extent of the surface plasmon. When that occurs, the surface plasmon will “jump” the predetermined gap and propagate from one plasmon guide to the other plasmon guide.