Abstract: Systems and methods are provided for applying directed energy to an object. The system includes a first transmitter comprising a light source configured to emit a first light beam at a first frequency towards a focal point and a second transmitter comprising a light source configured to emit a second light beam at a second frequency towards the focal point. The first and second light beams cause a third light beam to be generated that has a third frequency that is coincident with at least one resonant frequency of the object.

Abstract: An apparatus and method for modifying an electromagnetic beam. A metamaterial structure is positioned relative to a transmitting device such that an electromagnetic beam transmitted by the transmitting device passes through the metamaterial structure. The electromagnetic beam has a wavefront with a Gaussian intensity profile. The wavefront of the electromagnetic beam is modified as the electromagnetic beam passes through the metamaterial structure such that the Gaussian intensity profile of the wavefront is changed to a Bessel intensity profile.

Abstract: A method and apparatus for detecting an object. A first optical signal having a first frequency is transmitted to a location on a surface of a ground. A second optical signal having a second frequency is transmitted to the location on the surface of the ground such that the first optical signal and the second optical signal overlap each other at the location on the surface of the ground. The overlap of the first optical signal and the second optical signal at the location generates a third optical signal having a difference frequency that is a difference between the first frequency and the second frequency. The third optical signal is configured to travel into the ground. A response to the third optical signal is detected. A determination is made as to whether an object is present in the ground using the response to the third optical signal.

Abstract: A method and apparatus for forming and distributing quantum encryption keys. A first quantum signal generated by a number generator in a communicator is transmitted through an aperture in the communicator to a receiving communicator. A second quantum signal is received through the aperture at the communicator from a transmitting communicator. The first quantum signal is isolated from the second quantum signal such that the first quantum signal is transmitted from the communicator in response to the first quantum signal passing through the aperture and such that the second quantum signal is received at a number detector in the communicator in response to the second quantum signal passing through the aperture.

Abstract: A detection system for detecting an object includes a transmitter including a light source configured to emit a first light beam having a first frequency towards the object. The detection system also includes a receiver configured to receive a second light beam reflected from the object, and a detector positioned within the receiver. The second light beam has a second frequency as a result of a non-linear optical response of a surface of the object to the first light beam. The detector is configured to detect the object based on the second frequency of the second light beam.

Abstract: A mobile platform includes a sensor configured to collect raw data, a memory device, and a first processing device coupled to the sensor and to the memory device. The first processing device is configured to receive raw data from the sensor and determine, based on a significance of the raw data, whether to store the raw data in the memory device or to transmit the raw data.

Abstract: In one aspect, methods of making a carbon coating are described herein. In some implementations, a method of making a carbon coating comprises applying a first adhesive material to a substrate surface to provide an adhesive surface; rolling a carbon source over the adhesive surface to provide a carbon layer on the adhesive surface; and rolling an adhesive roller over the carbon layer to remove some but not all of the carbon of the carbon layer to provide the carbon coating.

Abstract: In one aspect, methods of coating a surface with carbon are described herein. In some implementations, a method of coating a surface with carbon comprises electrically charging carbon particles; directing the charged carbon particles toward an electrically charged surface; and contacting the charged carbon particles with the electrically charged surface. In some implementations, the method further comprises forming a coating of physisorbed carbon particles on the surface.

Abstract: An apparatus, system, and method are disclosed for a frequency selective electromagnetic detector. In particular, the frequency selective electromagnetic detector includes a nanowire array constructed from a plurality of nanowires of different compositions. At least one nanoparticle-sized diameter thermoelectric junction is formed between the nanowires of different compositions. When a nanoparticle-sized diameter thermoelectric junction senses a photon, the nanoparticle-sized diameter thermoelectric junction emits an electrical pulse voltage that is proportional to an energy level of the sensed photon. In one or more embodiments, the frequency selective electromagnetic detector is a frequency selective optical detector that is used to sense photons having optical frequencies. In at least one embodiment, at least one of the nanowires in the nanowire array is manufactured from a compound material including Bismuth (Bi) and Tellurium (Te).

Abstract: A thermally managed Li-ion battery assembly including an anode and a cathode, wherein at least one of the anode and the cathode includes a thermocrystal metamaterial structure.

Abstract: In one aspect, touch screens are described herein. In some implementations, a touch screen comprises an electrically conductive layer and one or more electrodes electrically connected to the electrically conductive layer, wherein the electrically conductive layer comprises a graphene layer. In some implementations, the electrically conductive layer comprises an electrically conductive coating disposed on an electrically insulating substrate.

Abstract: The present disclosure provides a system, method, and apparatus for detection and imaging. In one or more embodiments, the disclosed method involves transmitting, with a first optical transmitter, a first transmit signal to an object (e.g., a wire); and transmitting, with a second optical transmitter, a second transmit signal to the object. The method further involves receiving, with an optical receiver, a receive signal that is reflected from the object. In one or more embodiments, the receive signal is a function of the first transmit signal and the second transmit signal. Further, the method involves detecting, with a detector, the receive signal. The frequency of the receive signal is the sum of the frequency of the first transmit signal and the frequency of the second transmit signal, and/or is the difference between the frequency of the first transmit signal and the frequency of the second transmit signal.

Abstract: A method and apparatus for processing light. An apparatus comprises a light collector and a wire. The light collector is configured to receive light and direct the light to a location. The wire is in the location and is configured to generate an electrical signal in response to a number of photons of the light absorbed by the wire. The electrical signal generated by the wire includes information about a frequency of the number of photons.

Abstract: A method and apparatus comprising a signal generator and a wire. The signal generator is configured to generate an electrical signal having an amplitude. The wire is connected to the signal generator. The wire is configured to emit photons in response to receiving the electrical signal. The photons have a frequency based on the amplitude of the electrical signal.

Abstract: A method and apparatus comprising a signal generator, an array of wires, and a controller. The signal generator is configured to generate electrical signals. The electrical signals have amplitudes and first phases. The array of wires is connected to the signal generator. The array of wires is configured to emit photons having phases in response to receiving the electrical signals. The photons have frequencies based on the amplitudes of the electrical signals and second phases based on the first phases of the electrical signals. The controller is connected to the signal generator. The controller is configured to control the first phases of the electrical signals such that a desired radiation pattern for the photons emitted by the array of wires moves in a desired direction.

Abstract: An apparatus, system, and method are disclosed for a frequency selective electromagnetic detector. In particular, the frequency selective electromagnetic detector includes a nanowire array constructed from a plurality of nanowires of different compositions. At least one nanoparticle-sized diameter thermoelectric junction is formed between the nanowires of different compositions. When a nanoparticle-sized diameter thermoelectric junction senses a photon, the nanoparticle-sized diameter thermoelectric junction emits an electrical pulse voltage that is proportional to an energy level of the sensed photon. In one or more embodiments, the frequency selective electromagnetic detector is a frequency selective optical detector that is used to sense photons having optical frequencies. In at least one embodiment, at least one of the nanowires in the nanowire array is manufactured from a compound material including Bismuth (Bi) and Tellurium (Te).

Abstract: A free-space, decentralized, distributed computing network may comprise at least one free-space dynamic memory unit, at least one free-space processing unit, at least one free-space static memory unit, and at least one free-space communications link. The free-space dynamic memory unit may store data. The free-space processing unit may process the data, stored by the free-space dynamic memory unit, into information. The free-space static memory unit may provide operational instructions to the free-space dynamic memory unit and to the free-space processing unit. The free-space communications link may connect in the free-space the free-space dynamic memory unit, the free-space processing unit, and the free-space static memory unit. The free-space dynamic memory unit, the free-space processing unit, and the free-space static memory unit may each comprise at least one tracking device, and a transducer, transmitter, and/or receiver.

Abstract: A method and apparatus comprising a signal generator and wires. The signal generator is configured to generate electrical signals. The electrical signals have amplitudes and first phases. The wires are connected to the signal generator. The wires are configured to emit photons having phases in response to receiving the electrical signals. The photons have frequencies based on the amplitudes of the electrical signals and second phases based on the first phases of the electrical signals. The first phases of the electrical signals are selected such that the photons have a desired radiation pattern.

Abstract: An apparatus, system, and method are disclosed for a frequency selective imager. In particular, the frequency selective imager includes an array of pixels arranged in a focal plane array. Each pixel includes at least one nanoparticle-sized diameter thermoelectric junction that is formed between nanowires of different compositions. When a nanoparticle-sized diameter thermoelectric junction senses a photon, the nanoparticle-sized diameter thermoelectric junction emits an electrical pulse voltage that is proportional to an energy level of the sensed photon. In one or more embodiments, the frequency selective imager is a frequency selective optical imager that is used to sense photons having optical frequencies. In at least one embodiment, at least one of the nanowires in the frequency selective imager is manufactured from a compound material including Bismuth (Bi) and Tellurium (Te).

Abstract: An apparatus, system, and method are disclosed for nonlinear optical surface sensing with a single thermo-electric detector. In particular, the system includes at least two signal sources that are co-aligned to propagate photons to the same location on a surface. The system also includes at least one focusing element that focuses a sequence of photons that is reflected from the location on the surface. In addition, the system includes at least one frequency selective electromagnetic detector that detects the sequence of photons that are focused from the focusing element(s). When the frequency selective electromagnetic detector senses a photon, the frequency selective electromagnetic detector emits an electrical pulse that has a voltage that is proportional to the energy level of the photon. Additionally, the system includes a processor that processes the electrical pulses, and de-multiplexes the sequence of emitted electrical pulses based on the electrical pulse voltage of the electrical pulses.