Abstract: This is generally a method of producing graphene-containing suspensions of flakes of high quality graphene/graphite oxides and method of producing graphene/graphite oxides. Both the exfoliating graphite into flakes and oxidizing the graphite flakes and the preparation and suspension of the flakes can be done with high volume production and at a low cost.

Abstract: Graphene has been used in nanocomposites as constituents/doping in plastics or epoxy providing dramatic enhancement of the mechanical properties but have not progressed past the laboratory level novelty. This invention can provide a graphene based composite structure with a density less that 1.9 g/cm3 for a fiber, yarn, rope or cable and a density less that 1.5 g/cm3 for a sheet both structure have tensile and shear strength greater than either Aluminum or Steel; thus providing a graphene material that is both much lighter and stronger.

Abstract: This is a way interrogating an object using retro-reflection of non-visible light. It uses e.g. IR transmitted toward the object from a distance and covertly detects the retro-reflection. Highly reflective passive non-visible light retroreflectors on the object reflects and refracts light back toward the light transmitter, with the returned light being very nearly parallel to the light from a narrow beam light transmitter.

Abstract: This describes an enhanced retro-reflector that is designed to be a retro-reflector of non-visible light, but not visible, and can be designed to resemble common dust or dirt in the visible spectra. As the beads retro-reflect very little visible light they are not easily seen in visible light; thus they are difficult to counterfeit.

Abstract: The use of multiple pulses having controllable temporal relationships can produce higher optical ablative pulse peak power using split by color pulses. Split pulses can be controllably delayed to increase pulse peak power, average power and/or repetition rate in single-amplifier or multi-amplifier systems.

Abstract: The present invention includes an apparatus and method of surgical ablative material removal “in-vivo” or from an outside surface with a short optical pulse that is amplified and compressed using either an optically-pumped-amplifier and air-path between gratings compressor combination or a SOA and chirped fiber compressor combination, wherein the generating, amplifying and compressing are done within a portable system.

Abstract: The present invention includes an apparatus and method of surgical ablative material removal “in-vivo” or from an outside surface with a short optical pulse that is amplified and compressed using either an optically-pumped-amplifier and air-path between gratings compressor combination or a SOA and chirped fiber compressor combination, wherein the generating, amplifying and compressing are done within a portable system.

Abstract: The present invention includes an apparatus and method of surgical ablative material removal “in-vivo” or from an outside surface with a short optical pulse that is amplified and compressed using either an optically-pumped-amplifier and air-path between gratings compressor combination or a SOA and chirped fiber compressor combination, wherein the generating, amplifying and compressing are done within a portable system.

Abstract: The high-power-optical-amplifier of the present invention uses a number of spaced, thin slabs (e.g., disc-shaped doped-slabs that are stacked, with a space between discs), aligned to give an amplifier both with a high active cross-section and a very high surface area to volume ratio. More specifically, the present invention provides several methods that include the steps of aligning at least two or four slabs having a thickness dimension of less than one centimeter, substantially parallel to, and spaced from adjacent slabs, wherein the slab surfaces are rendered essentially non-reflective, optically pumping the slabs and passing an input beam through the surfaces wherein the beam is optically amplified in the slabs, and wherein the input beam is of an eye-safe wavelength.

Abstract: The present invention includes a method of fabricating an optically-pumped disk-array solid-state laser amplifier having one or more disks, wherein one or more of the one or more disks having two opposed surfaces, including the steps of patterning a photoresist mask on one or more of the two opposed surfaces of the one or more disks and processing the one or more disks through the patterned photoresist mask, whereby the temperature profile improved radially across the disk's surface, amplified spontaneous emission are reduced, or combinations thereof.

Abstract: The present invention includes an apparatus and method of surgical ablative material removal “in-vivo” or from an outside surface with a short optical pulse that is amplified and compressed using either an optically-pumped-amplifier and air-path between gratings compressor combination or a SOA and chirped fiber compressor combination, wherein the generating, amplifying and compressing are done within a man-portable system.

Abstract: The present invention includes an apparatus and method of surgical ablative material removal “in-vivo” or from an outside surface with a short optical pulse that is amplified and compressed using either an optically-pumped-amplifier and air-path between gratings compressor combination or a SOA and chirped fiber compressor combination, wherein the generating, amplifying and compressing are done within a portable system.

Abstract: Our wafer scale processing techniques produce chip-laser-diodes with a diffraction grating (78) that redirects output light out the top (88) and/or bottom surfaces. Generally, a diffraction grating (78) and integrated lens-grating (78) are used herein to couple light from the chip to an output fiber (74), and the lens-grating (78) is spaced from the diffraction grating (76). Preferably the diffraction grating (76) and integrated lens grating (78) are also used to couple light from the output fiber (74) back to the active region of the chip. The integrated lens-grating (78) can be in a coupling block (82). The use of a coupling block (82) can eliminate “facet-type damage”. A coupling block (82) is generally used herein to couple light from the chip to an output fiber (74), and preferably to couple feedback reflected from the fiber (74) back to the chip.

Abstract: The high-power-optical-amplifier of the present invention uses a number of spaced, thin slabs (e.g., disc-shaped doped-slabs that are stacked, with a space between discs), aligned to give an amplifier both with a high active cross-section and a very high surface area to volume ratio. More specifically, the present invention provides several methods that include the steps of aligning at least two or four slabs having a thickness dimension of less than one centimeter, substantially parallel to, and spaced from adjacent slabs, wherein the slab surfaces are rendered essentially non-reflective, optically pumping the slabs and passing an input beam through the surfaces wherein the beam is optically amplified in the slabs, and wherein the input beam is of an eye-safe wavelength.

Abstract: The present invention provides a method of amplifying a beam of laser pulses by producing an amplified collimated beam of pulses using an amplifier, spatially spreading the amplified collimated beam of pulses into an expanded beam of pulses, introducing the expanded beam of pulses into the amplifier a second time to produce a twice amplified beam of pulses, recollimating the twice amplified beam of pulses to produce a twice amplified collimated beam of pulses such that the twice amplified collimated beam of pulses is of essentially the same cross-section as the amplifier, and introducing the twice amplified collimated beam of pulses into the amplifier a third time to produce a thrice amplified collimated beam of pulses such that the re-collimated beam sweeps essentially the entire volume of the amplifier.

Abstract: The present invention includes a method of fabricating an optically-pumped disk-array solid-state laser amplifier having one or more disks, wherein one or more of the one or more disks having two opposed surfaces, including the steps of patterning a photoresist mask on one or more of the two opposed surfaces of the one or more disks and processing the one or more disks through the patterned photoresist mask, whereby the temperature profile improved radially across the disk's surface, amplified spontaneous emission are reduced, or combinations thereof.

Abstract: The present invention includes an apparatus and the method for remotely controlling an ablation beam for removal of material from a body so that it to impinge at various locations on the surface and can be remotely blocked or enabled, when monitored with a video camera to view the body surface in an isolated environment.

Abstract: The present invention includes an apparatus and method of surgical ablative material removal “in-vivo” or from an outside surface with a short optical pulse that is amplified and compressed using either an optically-pumped-amplifier and air-path between gratings compressor combination or a SOA and chirped fiber compressor combination, wherein the generating, amplifying and compressing are done within a man-portable system.

Abstract: The present invention is a system and method of ablation laser-machining, that includes the steps of generating pulses at 1 to 50 MHz by one or more semiconductor-chip laser diodes, each pulse having a pulse-duration less than three picoseconds, directing a less than 1 square mm beam of the pulses to a work-piece with an ablating pulse-energy-density; and scanning the beam with a power-driven scanner to ablate a scanned area at least 25 times larger than the beam area.

Abstract: Our wafer scale processing techniques produce chip-laser-diodes with a diffraction grating (78) that redirects output light out the top (88) and/or bottom surfaces. Generally, a diffraction grating (78) and integrated lens-grating (78) are used herein to couple light from the chip to an output fiber (74), and the lens-grating (78) is spaced from the diffraction grating (76). Preferably the diffraction grating (76) and integrated lens grating (78) are also used to couple light from the output fiber (74) back to the active region of the chip. The integrated lens-grating (78) can be in a coupling block (82). The use of a coupling block (82) can eliminate “facet-type damage”. A coupling block (82) is generally used herein to couple light from the chip to an output fiber (74), and preferably to couple feedback reflected from the fiber (74) back to the chip.