Abstract: A field emission device is disclosed having a buffer layer positioned between an underlying cathode conductive layer and an overlying resistor layer. The buffer layer consists of substantially undoped amorphous silicon. Any pinhole defects or discontinuities that extend through the resistor layer terminate at the buffer layer, thereby preventing the problems otherwise caused by pinhole defects. In particular, the buffer layer prevents breakdown of the resistor layer, thereby reducing the possibility of short circuiting. The buffer layer further reduces the risk of delamination of various layers or other irregularities arising from subsequent processing steps. Also disclosed are methods of making and using the field emission device having the buffer layer.

Abstract: A sodium-containing glass substrate has a modified surface on which an electroconductive film is to be formed. The modified surface is constituted of a layer of which sodium concentration is lower than the bulk body of the glass substrate, preferably with a sodium content ratio to all the metal elements of not greater than 2 atomic percent. The modified surface may contain a reduced amount of sulfur as compared to the bulk body of the glass substrate.

Abstract: A lamp vessel is made from a material which absorbs short-wave UV radiation. In addition, the luminescent screen comprises cerium-activated lunthanum phosphate and a luminescent substance having an emission band whose maximum is situated in the wavelength range from 340 nm and whose half-value ranges between 35 nm and 80 nm. The emission spectrum of the lamp for wavelengths below 400 nm corresponds closely to the solar spectrum while the lamp also has a high erythema L light output.

Abstract: A thin non-conductive fluorocarbon polymer layer is advantageously used in electroluminescent devices.

Abstract: An electroluminescent device including a layer of electroluminescent organic semiconductor material between a first transparent electrode of an n-type semiconductor material selected from nitrides and inorganic oxides, and a second electrode.

Abstract: An electron-emitting device contains a lower conductive region (22), a porous insulating layer (24A, 24B, 24D, 24E, or 24F) overlying the lower conductive region, and a multiplicity of electron-emissive elements (30, 30A, or 30B) situated in pores (281) extending through the porous layer. The pores are situated at locations substantially random relative to one another. The lower conductive region typically contains a highly conductive portion (22A) and an overlying highly resistive portion (22B). Alternatively or additionally, a patterned gate layer (34B, 40B, or 46B) overlies the porous layer. Openings (36, 42, or 541) corresponding to the filaments extend through the gate layer at locations generally centered on the filaments such that the filaments are separated from the gate layer.

Abstract: A field emission device (110, 210, 310, 410) includes an electron emitter (124), a first dielectric focusing layer (122) defining a first aperture (127), and a second dielectric focusing layer (123) defining a second aperture (133). Second dielectric focusing layer (123) is disposed on first dielectric focusing layer (122). The dielectric constant of second dielectric focusing layer (123) is less than the dielectric constant of first dielectric focusing layer (122). During the operation of field emission device (110, 210, 310), electron emitter (124) emits an electron beam (134), which is focused as it travels through first aperture (127) and then through second aperture (133).

Abstract: An electron emitting device characterized by a monocrystalline substrate, a plurality of monocrystalline nanomesas or pillars disposed on the substrate in a spaced relationship and extending generally normally therefrom, monocrystalline self-assembled tips disposed on top of the nanomesas, and essentially atomically sharp apexes on the tips for field emitting electrons. A method for making the emitters is characterized by forming a gate electrode and gate electrode apertures before forming the tips on the nanomesas.

Abstract: The lamp is provided with a metal holder (21) having an opening (21a) and resilient body (20) which fastens the holder in a tube (15) which is in communication with the discharge space. A first portion (20a) of the resilient body (20) is clamped in the opening (21a) of the holder (21). A second folded portion (21b) is clamped in inside the tube (15).

Abstract: A starting aid for a metal halide discharge lamp. An arc discharge tube is positioned in a hermetically sealed jacket. The jacket contains a partial pressure (e.g., 400 torr nitrogen) of a gas that will aid in starting the discharge and one of the arc tube lead-ins has an electrical conductor affixed thereto and exposed to the partial pressure of the gas. An outer conductor extends on the outside of the jacket and is electrically connected to the other lead-in. When voltage is applied to the electrodes a capacitive coupling takes place between the inner conductor and the outer conductor which generates a discharge that causes a breakdown in the arc generating and sustaining medium within the arc tube and causes the lamp to start.

Abstract: An electron-emitting device contains an emitter electrode (12), a group of sets of electron-emitting elements (24), a group of control electrodes (28), and a focusing system (37) for focusing electrons emitted by the electron-emissive elements. The sets of electron-emissive elements are arranged generally in a line extending in a specified direction. Each control electrode has a main portion (30) and a gate portion (32). the electron-emissive elements are exposed through gate openings (36) in the gate portion. The main portion of each control electrode crosses over the emitter electrode and has a large control opening (34) which laterally circumscribes one of the sets of electron-emissive elements. The focusing system has a group of focus openings (40) located respectively above the control openings. Each control opening is largely centered on, or/and is no more than 50% as large as, the corresponding focus opening in the specified direction.

Abstract: A semiconductor cathode (11) in a semiconductor structure, in which the sturdiness of the cathode is increased by covering the emitting surface (4) with a layer of a semiconductor material (7) having a larger bandgap than the semiconductor material of the semiconductor cathode. Various measures for increasing the electron-mission efficiency are indicated.

Abstract: An organic electroluminescent device comprises an electroluminescent unit having an organic layer structure provided between a pair of electrodes and capable of emitting light on application of a voltage thereto. The electroluminescent unit is covered with a protective double layer made of an organic barrier layer and an inorganic barrier layer formed on the unit in this order.

Abstract: The present invention relates to a plasma display device. The plasma display device comprises a rectangular plasma display panel for displaying images, a rectangular side frame installed along four sides of the plasma display device, a rectangular rear plate vertically installed on a rear aspect of the four sides of the side frame for protecting the plasma display device, and a supporting rack installed inside the side frame between the plasma display panel and the rear plate comprising a top beam, a bottom beam, and a plurality of vertical columns vertically installed between the top beam and bottom beam. The vertical spaces between neighboring vertical columns and the vertical spaces between the vertical columns and the left and right bars of the side frame are heat dissipation channels for directing the heat generated from the rear side of the plasma display panel upward and away from the plasma display device.

Abstract: A low pressure mercury vapor discharge lamp includes a bulb and a mercury-releasing metal substrate, in particular, an alloy of zinc and mercury in which the mercury-releasing metal substrate has an inside part crystallized in a plate form or in a granular form and a surface on which a mercury-rich layer is formed. The mercury-releasing metal substrate, in particular, the alloy of zinc and mercury, can be adhered firmly to the inside face of the bulb. Moreover, the low pressure mercury vapor discharge lamp can be made by putting a mercury-releasing metal substrate into a bulb; forming a mercury-rich layer on the surface of the mercury-releasing metal substrate while crystallizing the inside of the mercury-releasing metal substrate in a plate form or in a granular form by heating the bulb from the outside; and softening the mercury-releasing metal substrate to adhere it to the inside face of the bulb.

Abstract: The present case relates to a gas discharge display, represented with a plasma display panel(PDP), for displaying an image by displaying gradation using a discharge characteristic of a particular gas. Of a background art gas discharge display for displaying an image by means of a gas discharge having transparent front, and back substrates supported by barrier ribs of a fixed length from inside thereof, electrodes, dielectric, and protective film provided inside of the front, and back substrates, and Penning gas of two gases (Ne+Xe, He+Xe, and etc.) or Penning gas of three gases (Ne+Xe+Ar, He+Xe+Ar, Ne+Xe+He) filled in spaces of the two protective films as a discharge gas, a Penning gas of four gases (Ne+He+Xe+Ar) is used in the gas discharge display for improving a luminance.

Abstract: A getter (74) is situated in an auxiliary compartment (72) of a hollow structure (40-46 and 76) having a larger main compartment (70). The auxiliary compartment is situated outside the main compartment and is connected to the main compartment so that the two compartments reach largely the same steady-state compartment pressure. The getter is activated by directing light energy locally through part of the hollow structure and onto the getter. The light energy is typically furnished by a laser beam (60). The getter, typically of the non-evaporable type, is usually inserted as a single piece of gettering material into the auxiliary compartment. The getter normally can be activated/re-activated multiple times in this manner, typically during sealing of different parts of the structure together.

Abstract: In a plasma display device having a three-dimensional matrix wiring arrangement of anodes, cathodes and address electrodes, writing discharge is caused between anodes and address electrodes to temporarily store writing charge on a dielectric layer, and the writing charge is discharged as an auxiliary discharge by applying a sustaining voltage to the cathodes, thereby inducing main discharge between the anodes and the cathodes.

Abstract: A color cathode ray tube has a vacuum vessel including a panel portion having a phosphor screen on its inner face, a neck portion and a funnel portion jointing the neck portion and the panel portion; an electron gun assembly including an electrostatic main lens disposed in the neck portion; a deflection yoke arranged around the neck side of the funnel portion for deflecting three in-line arranged electron beams emitted from the electron gun assembly to the phosphor screen; and a 2-pole ring magnet arranged around the neck portion for adjusting the trajectories of the electron beams. The 2-pole ring magnet is arranged to have its center closer to the phosphor screen than is the center of the electrostatic main lens of the electron gun assembly. The value, as calculated by dividing the value of the radial component amplitude of the magnetic field distribution of the 2-pole ring magnet on the circumference of a circle having a radius of the s-size, by the value of the circumferential component amplitude, is 0.

Abstract: An electrodeless gas discharge light assembly includes a lamp base (12) having a pair of light-transmitting lenses (14, 16) supported in axially opposed relation to one another. An electrodeless gas discharge light source (28) is mounted between the lenses (14, 16) and comprises a generally flat spiral induction coil (30) sandwiched between a pair of generally flat, planar envelopes (32, 34) in which an ionizable gas (46) is contained. Energizing the coil (30) inductively induces discharge illumination of the gas (46) causing light to be emitted in axially opposite directions through the lenses (14, 16) without obstruction by the coil (30).