Abstract: A system for providing electrical and optical interconnection using a 3D non-carbon-based topological insulator (TI) is disclosed. The system includes a length of the TI having a tube shape having wall thickness of about 10 nm to about 200 nm and a hollow interior portion surrounded by an interior surface of the TI. The length includes a first end and a second end, wherein the first end is configured to receive an optical signal, an electrical signal, or both. The optical signal propagates in the hollow interior portion along the length to the second end by total internal reflection due to a refractive index of the interior surface of the TI. The electrical signal propagates along an external surface of the TI to the second end.

Abstract: A nanotube particle device for two dimensional and three dimensional printing or additive/subtractive manufacturing. The nanotube particle device comprising a nanotube, a particle shooter, a positioning mechanism, and a detection sensor. The particle shooter shoots a particle down the nanotube towards a target, the detection sensor senses the collision of the particle with the target, and the positioning mechanism re-adjusts the positioning of the nanotube based on the results of the collision. A method for aiming the particle shooter and additive/subtractive manufacturing are also disclosed and described.

Abstract: A system for encrypting data and transferring or storing data securely may include a computing device including an encryptor configured to generate an encryption key from a network resource and encrypt data using the encryption key to generate encrypted data, and a decryptor configured to generate a decryption key from the network resource and decrypt the encrypted data to generate the non-encrypted data.

Abstract: In one aspect, thermally managed electronic components are described herein. In some implementations, a thermally managed electronic component comprises an electronic component and a thermal management coating disposed on a surface of the electronic component. The thermal management coating comprises a graphene coating layer disposed on the surface of the component. The graphene coating layer may comprise a layer of aligned carbon nanoparticles. Moreover, the thermal management coating may further comprise an additional layer of aligned carbon nanoparticles disposed on the graphene coating layer. In another aspect, methods of applying a thermal management coating on an electronic component are disclosed. In some implementations, such a method comprises disposing a graphene coating layer on a surface of an electronic component. The graphene coating layer may comprise a layer of aligned carbon nanoparticles.

Abstract: A method and apparatus for transmitting secure data packets through a node network. Unsecure data packets are received at a set of unsecure inputs and secure data packets are received at a number of secure inputs in a node in the node network. The secure data packets are authorized to be sent to a number of secure destination devices. The unsecure data packets are not authorized to be sent to the number of secure destination devices. The secure data packets and the unsecure data packets are integrated to form a number of output data streams based on a predetermined schedule. The number of output data streams is sent to a number of next nodes in the node network.

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: A method may include generating one or more control signals configured to control a velocity of an image sensing system based on a rate of recording pixels frames in the image sensing system. In some embodiments, the method may alternatively or additionally include generating one or more control signals configured to control the rate of recording in the image sensing system based on the velocity of the image sensing system. In some embodiments, a portion of image pixel data for a pixel frame may be output for transmission to a remote receiver. In some embodiments, the output data may include a recently recorded image data pixel for those surface resolution cells for which there is no currently stored reference image data pixel of a previously recorded pixel frame that is the same or is different by less than a threshold amount as the recently recorded image data pixel.

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, 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: 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: 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 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: A nanotube particle device for two dimensional and three dimensional printing or additive/subtractive manufacturing. The nanotube particle device comprising a nanotube, a particle shooter, a positioning mechanism, and a detection sensor. The particle shooter shoots a particle down the nanotube towards a target, the detection sensor senses the collision of the particle with the target, and the positioning mechanism re-adjusts the positioning of the nanotube based on the results of the collision. A method for aiming the particle shooter and additive/subtractive manufacturing are also disclosed and described.

Abstract: A method may include generating one or more control signals configured to control a velocity of an image sensing system based on a rate of recording pixels frames in the image sensing system. In some embodiments, the method may alternatively or additionally include generating one or more control signals configured to control the rate of recording in the image sensing system based on the velocity of the image sensing system. In some embodiments, a portion of image pixel data for a pixel frame may be output for transmission to a remote receiver. In some embodiments, the output data may include a recently recorded image data pixel for those surface resolution cells for which there is no currently stored reference image data pixel of a previously recorded pixel frame that is the same or is different by less than a threshold amount as the recently recorded image data pixel.

Abstract: A method and apparatus for sending encrypted data across a node in a communications network. In one illustrative embodiment, an apparatus comprises a first communicator, a second communicator, and a number of nodes. The first communicator is configured to encrypt unencrypted data to form the encrypted data using a first quantum key distributor. The second communicator is configured to decrypt the encrypted data using a second quantum key distributor. The number of nodes is configured to receive the encrypted data sent from the first communicator and send the encrypted data to the second communicator using quantum teleportation. The encrypted data remains encrypted as the encrypted data passes through each of the number of nodes.

Abstract: A system for encrypting data and transferring or storing data securely may include a computing device including an encryptor configured to generate an encryption key from a network resource and encrypt data using the encryption key to generate encrypted data, and a decryptor configured to generate a decryption key from the network resource and decrypt the encrypted data to generate the non-encrypted data.

Abstract: In one aspect, coated electrical components are described herein. In some implementations, a coated electrical component comprises an electrical component and a graphene coating layer disposed on a surface of the electrical component. The graphene coating layer, in some implementations, has a thickness of about 300 nm or less. In another aspect, methods of increasing the service life of an electronic apparatus are disclosed herein. In some implementations, such a method comprises disposing a graphene coating layer on an environment-facing surface of an electronic component of the apparatus, wherein the electronic apparatus exhibits at least a 10 percent improvement in environmental testing performance compared to an otherwise equivalent electronic apparatus not comprising a graphene coating layer, the environmental testing performance comprising performance in a waterproofness test, acetic acid test, sugar solution test, or methyl alcohol test described herein.

Abstract: In one aspect, thermally managed electronic components are described herein. In some implementations, a thermally managed electronic component comprises an electronic component and a thermal management coating disposed on a surface of the electronic component. The thermal management coating comprises a graphene coating layer disposed on the surface of the component. The graphene coating layer may comprise a layer of aligned carbon nanoparticles. Moreover, the thermal management coating may further comprise an additional layer of aligned carbon nanoparticles disposed on the graphene coating layer. In another aspect, methods of applying a thermal management coating on an electronic component are disclosed. In some implementations, such a method comprises disposing a graphene coating layer on a surface of an electronic component. The graphene coating layer may comprise a layer of aligned carbon nanoparticles.

Abstract: A method and apparatus for a device configured to communicate using an optical signal and an electrical signal through a connection to a tube comprised of a number of layers of carbon forming a wall of the tube. The number of layers of carbon has a number of optical properties configured to propagate the optical signal and a number of electrical properties configured to conduct the electrical signal.

Abstract: A method and apparatus for transmitting signals. An apparatus comprises a tube comprising a number of layers of carbon forming a wall of the tube. The number of layers of carbon has a number of optical properties configured to propagate an optical signal and a number of electrical properties configured to conduct an electrical signal.