Abstract: Optometaphoresis is a new form of software programmable optics wherein light is controlled by the migration of a large number of particles in a colloid due to radio frequency signals injected into the colloid by a near-field micro-structured current-voltage-energized phased-array antenna-electrode that impress dielectrophoretic forces and torques on nanoparticles in the colloid. This creates a fluidic metamaterial that affects the propagation of light (ultraviolet, visible light, infrared, THz waves, millimeter waves, etc.) passing through the colloid. The migration modalities of the particles include translation, orientation, and deformation of particles in a colloid. Optometaphoresis synthesis the central quantity to all optics: Refractive Index. Light may be refracted, reflected, diffracted, guided, and even polarized within the optometaphoresis system by bending light.

Abstract: Methods and devices are provided for the beam steering, focusing, display, and generation of light and images by electronically induced refractive index gradients and scattering fields formed by forces on particles in a colloid due to phoretic processes. The methods and devices provide control over multi-octave bandwidth and polarization diverse light having a large dynamic range in power handling. Embodiments of the technique are provided for large-angle beam steering, beam combining, focusing, and redirecting light electronically. Diverse applications for the technology include, but are not limited to: solar concentrators, LiDAR, robotic vision, smartphone zoom lenses, 3D-manufacturing, high-power laser machining, augmented & virtual reality displays, electronic paper displays, computer and television displays.

Abstract: Methods and embodiments are provided for the coordinated translation, rotation, and deformation of swarms of nanoparticles by means of forced diffusion by dielectrophoresis in order to affect the scattering of light and the synthesis of the central quantity to all optics: refractive index. Applications include electronic beam steering of light, concentration of sunlight, augmented reality displays, and medical diagnostics, and many others.

Abstract: Methods and devices are provided for the beam steering, focusing, display, and generation of light and images by electronically induced refractive index gradients and scattering fields formed by forces on particles in a colloid due to phoretic processes. The methods and devices provide control over multi-octave bandwidth and polarization diverse light having a large dynamic range in power handling. Embodiments of the technique are provided for large-angle beam steering, beam combining, focusing, and redirecting light electronically. Diverse applications for the technology include, but are not limited to: solar concentrators, LiDAR, robotic vision, smartphone zoom lenses, 3D-manufacturing, high-power laser machining, augmented & virtual reality displays, electronic paper displays, computer and television displays.

Abstract: A general method is provided for electronically reconfiguring the internal structure of a solid to allow precision control of the propagation of wave energy. The method allows digital or analog control of wave energy, such as but not limited to visible light, while maintaining low losses, a multi-octave bandwidth, polarization independence, large area and a large dynamic range in power handling. Embodiments of the technique are provided for large-angle beam steering, lenses and other devices to control wave energy.

Abstract: A general method is provided for electronically reconfiguring the internal structure of a solid to allow precision control of the propagation of wave energy. The method allows digital or analog control of wave energy, such as but not limited to visible light, while maintaining low losses, a multi-octave bandwidth, polarization independence, large area and a large dynamic range in power handling. Embodiments of the technique are provided for large-angle beam steering, lenses and other devices to control wave energy.

Abstract: An ultra-efficient device for converting light into electricity has a dielectric medium for input light propagation, a metallic medium having an array of surface-plasmon-polariton (SPP) resonator cavities formed at nano-scale and distributed in the metallic medium below the dielectric-metal interface, each nano-scale resonator cavity having a hollow interior as a metal cathode in which a metal anode is disposed, another metallic medium electrically coupled to the anode, and another dielectric medium insulating the anode medium from the cathode medium. In each cavity, the cathode is shaped, dimensioned and spaced from the anode so that standing waves of SPP excitations generated by the input light cause quantum field emission of electrons to be rectified as an electrical output. The SPP resonator cavities may be formed in a plurality of diametral sizes corresponding to component light wavelengths to allow full spectrum energy conversion of broadband light input.

Abstract: An ultra-efficient device for converting light into electricity has a dielectric medium for input light propagation, a metallic medium having an array of surface-plasmon-polariton (SPP) resonator cavities formed at nano-scale and distributed in the metallic medium below the dielectric-metal interface, each nano-scale resonator cavity having a hollow interior as a metal cathode in which a metal anode is disposed, another metallic medium electrically coupled to the anode, and another dielectric medium insulating the anode medium from the cathode medium. In each cavity, the cathode is shaped, dimensioned and spaced from the anode so that standing waves of SPP excitations generated by the input light cause quantum field emission of electrons to be rectified as an electrical output. The SPP resonator cavities may be formed in a plurality of diametral sizes corresponding to component light wavelengths to allow full spectrum energy conversion of broadband light input.

Abstract: A photon triggered RF radiator that is composed of a photoconductive subste having a ground plane electrode on its bottom surface and a top surface electrode having separate sections to perform energy storage and energy radiation functions. The energy storage section has a bulk-type photoconductive switch position therein such that any energy stored in the energy storage section of the top surface electrode is instantaneously discharged through the substrate to the ground plane, thus causing a pulse of nanosecond pulsewidth dimension to radiate from the energy radiation section of the top surface electrode.

Abstract: A photoconductive switch coupled to an energy storage device wherein the tch is comprised of photoconductive semiconductor material while the energy storage device comprises two spiral metalized arms that make up a spiral antenna. The photoconductive switch is electrically connected to the storage device to facilitate fast discharge of the stored energy through a load. A variation comprises a storage device comprising two separate pieces of substrate material each having a spiral metalized arm. The separate pieces being connected by highly dielectric material to form a spiral antenna ultra wideband radiator.

Abstract: A photoconductive switch coupled to an energy storage device wherein the tch is comprised of photoconductive semiconductor material while the energy storage device comprises two quasi-radial transmission line including a different material, i.e. a dielectric storage medium. The photoconductive semiconductor gallium arsenide switch is electrically connected to two quasi-radial transmission lines formed in part by layers of metallization configured in a quasi-radially shaped pattern upon the energy storage device. A variation comprises a photoconductive semiconductor gallium arsenide wafer sandwiched between two quasi-radial transmission lines so that the semiconductor gallium arsenide wafer serves as substrate, energy storage medium, and photoconductive switch.