Abstract: An electrical generator includes a magnet constrained to move relative to a conductor by a support structure, with a ferrofluid bearing providing an ultra low friction interface between the magnet and support structure. The assembly has a critical angle of displacement from a horizontal static position of less than 1 degree, and preferably less than 10 minutes. An electrical signal is generated in the conductor by the moving magnetic field.

Abstract: A dynamic magnet system, particularly useful for electrical generation, employs multiple magnets in polar opposition to each other for individual movement relative to a support structure. The magnets have a critical angle of displacement from a horizontal static position of less than 1 degree, with at least some of the magnets having mutually different properties. With different magnetic strengths, a greater movement is produced for both magnets in response to movements of the support structure, for particular ranges of magnetic strength ratios, than would be the case with equal magnets. The magnet movement can be translated into an electrical signal to power an operating system. Ultra low friction ferrofluid bearings can be used to establish static coefficients of friction between the magnets and support structure less than 0.02, enabling useful power generation from only slight movements of the support structure.

Abstract: A mechanical translator includes at least one magnet that is disposed on a substrate to carry a load and has a magnetic axis generally transverse to the substrate, establishing a magnetic field with maximum external density adjacent the substrate. An ultra low friction interface is obtained with ferrofluid bearings, such as a light mineral oil medium mixed with isoparaffinic acid, which establish a critical angle of displacement from a horizontal static position of less than 1 degree, and preferably less than 10 minutes. A controller of magnetic material can be placed on the opposite side of the substrate to control the movement of the magnets.

Abstract: Light emitters are formed and patterned on an electrode for an organic light-emitting device by electrochemically polymerizing a monomer across the full length of the electrode. A second electrode is deposited so to define a pixel region between mutually aligned portions of the two electrodes. Electroluminescence of the emitter occurs when a voltage is applied across the electrodes of the device.

Abstract: The present invention provides co-doped zinc oxide to flat panel, light emissive display devices and vacuum microelectronic devices to improve their efficiency and lifetime. This material has a low growth temperature and is compatible with metal oxide semiconductor (MOS) processing technology. It is tranparent, chemically stable and has a low work function, which result in many advantages when being used as the cathode for the aforementioned devices. In one embodiment of the emissive display device, an organic light diode (OLED) display has a high work function metal anode, such as platinum (Pt), gold (Au) or nickel (Ni) and a low work function co-doped zinc oxide cathode. Because of the energy level alignment provided by these two materials, the potential energy barriers to injection of electrons from the cathode and holes from the anode into the organic emissive medium are minimized so the display device operates more efficiently.

Abstract: A doped Cadmium Oxide (CdO) film has been developed for use in applications requiring conductive, films which are highly transparent to IR radiation. Suitable dopants for the film include any of the Group III elements, namely Boron, Aluminum, Gallium, Indium, or Thallium.

Abstract: The present invention relates to a novel zinc oxide thin film having hydrogen (H) and gallium (Ga) dopants. Advantageously, the activation temperature is low. The co-doped zinc oxide is highly conductive, transparent, chemically stable, easily deposited on a variety of substrates, including flexible or plastic substrates, and is well suited for electrical or optical applications. By co-doping with two impurities, both sides of the zinc oxide lattice contribute to the film conductivity resulting in high electron concentration and high mobility. The co-doped zinc oxide thin film has an increased Fermi level and a reduced work function that is less than 3 eV. The co-doped zinc oxide is crystal clear and transparent even when grown at relatively low processing temperatures. In another preferred embodiment of the present invention, a novel low-temperature activation indium tin oxide (ITO) thin film comprising tin oxide co-doped with indium (In) and hydrogen is disclosed.

Abstract: An ambient temperature solid state sensor for detecting the concentration of a gas includes an insulating substrate, a polycrystalline semiconducting oxide thin film deposited on the substrate such that the gas can be adsorbed on the surface of the film, the film having a low carrier concentration and a high resistivity, a pair of electrodes disposed on the film for measuring the electrical resistance of the film, and a source of light having a wavelength component which is absorbed by the thin film, thereby causing photodesorption of the gas from the surface of the film and establishing the equilibrium between gaseous species in the ambient and gaseous species adsorbed on the oxide surface. The resistance of the thin film is dependent on the amount of adsorbed gas, the measured resistance of the film thereby indicating the concentration of the gas.

Abstract: A method is provided for depositing a uniform thin film on a substrate using laser ablation of a target material in a deposition chamber. The laser beam may be pulsed and focused to strike the target along a line to produce a broad plume of ablated material expanding in a propagation direction outward from the target. The plane of the substrate deposition surface is oriented generally parallel to the propagation direction of the plume of ablated material. The deposition chamber includes a low background pressure of inert or reactive gas to facilitate lateral diffusion of ablated atoms, ions, and molecules to be deposited on the substrate surface. Particles ejected from the target material, which have trajectories generally parallel to the propagation direction of the plume, are too heavy to have significant lateral diffusion and have little chance of lodging on the deposition surface.

Abstract: A rotating cylindrical target surface is provided for the laser ablation process of depositing thin films on a substrate. The target is mounted in a vacuum chamber so that it may be rotated about the longitudinal axis of the cylindrical surface target and simultaneously translated along the longitudinal axis. A laser beam is focused by a cylindrical lens onto the target surface along a line that is at an angle with respect to the longitudinal axis to spread the plume of ablated material over a greater radial arc. The plume may be spread in the longitudinal direction by providing a concave or convex lateral target surface. The angle of incidence of the focused laser beam may be other than normal to the target surface to provide a more glancing geometry. Simultaneous roation about and translation along the longitudinal axis produce a smooth and even ablation of the entire cylindrical target surface and a steady evaporation plume.

Abstract: Thermal sources of Te and of Hg are provided in a vacuum chamber to furnish constant effusion of Te and Hg. Laser radiation is used to evaporate a beam of CdTe from a target of CdTe in the chamber. The laser radiation is modulated to vary the beam intensity of CdTe and thereby deposit a controlled compositional profile of Hg.sub.(1-x) Cd.sub.x Te on a substrate located in the chamber.

Abstract: Disclosed is an apparatus for depositing a layer of a material on a substrate and annealing the deposited layer, including a Q-switched Nd: YAG laser for providing a coherent light output. An up collimator is situated in the path of the coherent light output to increase the cross sectional area of the output, while a beam divider separates the output into first and second coherent beams. First and second lenses are adjustably positioned in the paths of the beams to focus the first beam on a source of the material and the second beam on the substrate. First and second x-y scanners are provided for scanning the first and second beams. A vacuum chamber includes a connection for a vacuum source and windows to admit the first and second beams into the chamber. A source support positions a source of the material within the chamber in the path of the first beam and a substrate support positions the substrate in the path of the second beam and at least 45.degree. away from the normal to the surface of the source.