Abstract: The electrode component according to the invention is produced by means of the metal powder injection molding method. As a result, complex shapes can be realized for the electrode.

Abstract: An electron discharge device characterized in having a conductive layer on one surface of a dielectric substrate, a dielectric layer and a conductive layer, in this order, on the other surface of the substrate, wherein the dielectric layer has a thickness equal to or less than 5 nm and a permittivity lower than that of the dielectric substrate. A method for discharging electrons from a surface of a conductive layer (2) by applying voltage between conductive layers (1) and (2) of a device having the conductive layer (1) on one surface of a dielectric substrate, a dielectric layer and the conductive layer (2), in this order, on the other surface of the substrate, wherein the dielectric layer has a thickness equal to or less than 5 nm and a permittivity lower than that of the dielectric substrate, such that a conductive layer (1) serves as a cathode and that the conductive layer (2) serves as an anode.

Abstract: The present invention provides an electrode for a ceramic electrode fluorescent discharge lamp; an electrode material for a discharge lamp, which has high electron flow density, high thermal shock resistance, and reduced deterioration due to sputtering; and also a method for manufacturing the same. The invention makes it possible to reduce the tube diameter of the ceramic electrode fluorescent discharge lamp. An electrode material for a discharge lamp is obtained from a first component of 0.5 to 1.5 mols of BaO, CaO or SrO, a second component of 0.05 to less than 0.3 mols or more than 0.7 to 0.95 mols of ZrO2 or TiO2, and a third component of 0.025 to less than 0.3 mols of V2O5, Nb2O5, Ta2O5, Sc2O3, Y2O3, La2O3, Dy2O3, or Ho2O3, or 0.05 to less than 0.15 mols or more than 0.35 to 0.95 mols of HfO2, CrO3, MoO3 or WO3. This electrode material is granulated and is turned into a massive, granular, or porous electrode material.

Abstract: A high-pressure metal halide discharge lamp has opposed tungsten electrodes carried by electrode rods. These rods have a first portion of tungsten adjacent the electrodes and a second portion made of at least 25% by weight of rhenium. Their common boundaries are at a location having an operating temperature in the range of 1900-2100° K. The gas filling contains metal oxyhalide and is devoid of rare earth metal compounds.

Abstract: A vessel has a main body and a plugging members made of alumina. First composite electrode has a cylindrical current conductor having substantially same diameter as a diameter of the opening portion at one end of the vessel, and an electrode jointed by welded at a bottom of the current conductor exposed to inside of the vessel. The current conductor of the first composite electrodes has a cylindrical member made of alumina and a metallization layer made of molybdenum and alumina. A ceramic discharge tube is made in that the vessel and a first composite electrode have been subjected to a co-firing into an integrated body, with the first composite electrode inserted into the opening portion at one end of the vessel so that the electrode is exposed to the inner space with one end of the first composite electrode is exposed to outside of the vessel.

Abstract: A vapor discharge lamp comprised of an arc tube containing an ionizable medium, a first electrode electrically connected to a first in lead conductor, and a second electrode electrically connected to a second in lead conductor, said first and said second electrode pairs being positioned to create an arc discharge therebetween, an electron emissive material disposed on at least one of said electrodes, said electron emissive material being Ba.sub.4 Al.sub.2 O.sub.7.

Abstract: A small fluorescent lamp having improved efficiency is described. The lamp includes a lamp body having a serpentine channel therein. The serpentine channel is arcuate in cross section with a fluorescent coating covering the serpentine channel but not the lamp cover to produce an aperture effect. The serpentine channel is reflective such that the cross section forms an aperture effect lamp to improve efficiency. Efficiency is further improved by raising the pressure within the lamp to 70-120 torr. Further efficiency is obtained by limiting the depth of the serpentine channel relative to the width of the serpentine channel such that the electrical discharge is confined within a small cross sectional area. In one embodiment, secondary housings are attached to the lower surface of the lamp to conceal the electrodes beneath the lamp, thereby improving the uniformity of the lamp.

Abstract: An electron emitter (121, 221, 321, 421) includes an electron emitter structure (118) having a passivation layer (120, 220, 320, 420) formed thereon. The passivation layer (120, 220, 320, 420) is made from an oxide selected from a group consisting of the oxides of Ba, Ca, Sr, In, Sc, Ti, Ir, Co, Sr, Y, Zr, Ru, Pd, Sn, Lu, Hf, Re, La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Th, and combinations thereof. In the preferred embodiment, the electron emitter structure (118) is made from molybdenum, and the passivation layer (120, 220, 320, 420) is made from an emission-enhancing oxide having a work function that is less than the work function of the molybdenum.

Abstract: The present invention is directed to a PDP device fabricated by using photosensitive thick film conductor compositions wherein a black electrode is present between the substrate and a conductor arrangement electrode. Also, the invention is directed to methods for fabricating the PDP device.

Abstract: The high-pressure metal halide discharge lamp has opposite tungsten electrodes (5) carried by electrode rods (7). These rods (7) have a first portion (71) of tungsten adjacent the electrodes (5) and a second portion (72) having a core of tungsten and a skin of at least 90% by weight of rhenium. Their common boundaries are at a location having during operation a temperature in the range of 1900-2100 K. The gas filling contains metal oxyhalide and is devoid of rare earth metal compounds. The lamp has a long life and a high luminous maintenance.

Abstract: The high-pressure metal halide discharge lamp comprises a quartz-glass lamp vessel (1) with an ionizable filling and two electrodes (2) which are connected to current conductors (3). The electrodes are provided with an emitter (6) which contains tungsten as a main component and at least three oxides, a first oxide which is chosen from hafnium oxide and zirconium oxide, a second oxide being lanthanum oxide, and a third oxide which is chosen from yttrium oxide.

Abstract: Novel emitter materials, electrode assemblies amd lamps comprising the same are provided in which, in accordance with the invention, novel electrodes are provided having a lamp electrode structure, preferably including a hollow ferrule for sealing in a lamp to permit evacuation; an emitter material of the invention on at least one surface thereof, preferably on a protrusion attached to the hollow ferrule; a thermal isolator, preferably in the form of a low thermal conductivity wire or an incised or cut-out portion of the hollow ferrule body, for thermally isolating the protrusion from the ferrule to maintain a sufficiently high temperature for thermionic emission, and further comprising an emitter material requiring no in-lamp processing. The emitter materials are a mixed oxide of Ba, Sr and mixtures thereof with one or more of the metals from the series comprising Ta, Ti, Zr, Sc, Y, and La, are preferably selected from the group consisting of Ba.sub.4 Ta.sub.2 O.sub.9, Ba.sub.5 Ta.sub.4 O.sub.15, BaY.sub.

Abstract: A high intensity lamp is provided based on an open discharge between a cathode grid anode and a collector. A phosphor layer on the collector is excited by an electron beam to produce light or ultraviolet radiation to produce light.

Abstract: Novel emitter materials, electrode assemblies amd lamps comprisinfg the same are provided in which, in accordance with the invention, novel electrodes are provided having a lamp electrode structure, preferably including a hollow ferrule for sealing in a lamp to permit evacuation; an emitter material of the invention on at least one surface thereof, preferably on a protrusion attached to the hollow ferrule; a thermal isolator, preferably in the form of a low thermal conductivity wire or an incised or cut-out portion of the hollow ferrule body, for thermally isolating the protrusion from the ferrule to maintain a sufficiently high temperature for thermionic emission, and further comprising an emitter material requiring no in-lamp processing. The emitter materials are a mixed oxide of Ba, Sr and mixtures thereof with one or more of the metals from the series comprising Ta, Ti, Zr, Sc, Y, and La, are preferably selected from the group consisting of Ba.sub.4 Ta.sub.2 O.sub.9, Ba.sub.5 Ta.sub.4 O.sub.15, BaY.sub.

Abstract: A mercury lamp of the short arc type with a high degree of maintenance of irradiance is achieved in a mercury lamp of the short arc type by the cathode containing thorium oxide and having a tungsten carbide layer on its surface except at tip end area, by at least one of the cathode or anode being provided with metallic tantalum, and by the condition 1.56.ltoreq.VT/SC being satisfied, where SC is the area of the tungsten carbide layer (cm.sup.2) and VT is the volume of the metallic tantalum (mm.sup.3). Alternatively, a high degree of maintenance of irradiance can be achieved in a mercury lamp of the short arc type by the condition 0.043.ltoreq.VT/VW being satisfied, where VW is the volume of the anode (cm.sup.3) and VT is the volume of the tantalum in the lamp bulb (mm.sup.3).

Abstract: A low pressure discharge lamp in which, even during uninterrupted operation, a low lamp voltage characteristic is maintained over a long time interval and in which high radiant efficiency can be obtained over a long time is achieved via a low pressure discharge lamp which has a tubular glass bulb in which a pair of electrodes are located opposite one another, by an electron emission material which contains lithium being included on or in the electrode substrate. Advantageously, the electron emission material contains at least one of the following materials: metallic lithium, an alloy of lithium and another metal, an oxide of lithium, a mixture of an oxide of lithium with another metal oxide, and an oxide which contains lithium and another metal element and which is a compound identified by the formula Li--M--O.sub.x where M designates at least one element selected from among the alkali earth metals, rare earth metals and transition metal, and x is the number of oxygen atoms required for valency equalization.

Abstract: A discharge lamp of the short arc type including an arc tube and an anode and cathode within the arc tube positioned opposite one another. The present invention includes an anode arrangement in which the temperature increase of the anode in luminous operation is suppressed as much as possible, in which blackening of the inside wall of the arc tube as a result of premature vaporization of the anode material is suppressed, and in which the durability of the above described lamp is prolonged. Specifically, the outer surface of the anode includes sintered layers of fine-particle tungsten adjacent the tip of the anode. In this way, the effective surface area of the anode is increased, the heat radiation from the anode is accelerated, and the premature vaporization of the anode material is suppressed.

Abstract: A conductive refractory compound coating for electrodes is sputter resistant, very resistant to oxidation, and easy to apply by way of electrophoresis or screen printing. This structure is further enhanced by the presence of surface particles of electrically nonconductive ceramic material. When the cathode electrode is energized, electrically nonconductive material is penetrated by the electric field, which attracts secondary electrons out of the cathode electrode, thereby increasing the cathode's efficiency as an emitter of secondary electrons. More specifically, cathode electrodes are used in a plasma addressing structure. The coating is formed by approximately 5 nm particles, each comprised of a fused matrix of conductive and nonconductive particles co-deposited with frit particles by either electrophoresis or "silk" screening. The coating is subsequently baked to fuse the frit and bond the electrophoretically deposited particles to the electrodes.

Abstract: A high intensity discharge lamp with a heat treated inner electrode rod has been found to form an advantageous crack pattern. As a result seal failures have been reduced and lamp life increased.

Abstract: An organic electroluminescent element ("organic EL element") capable of emitting light with high luminance by driving at a low voltage, and inhibiting deterioration in organic layers is provided. A surface treatment of an indiumtin oxide (ITO) transparent electrode with a titanate coupling agent containing phosphorus in the side chain thereof improves adhesion between the ITO transparent electrode and an organic hole transport layer. As a result, it is possible to increase the efficiency of injection of holes, improve low-voltage driving and luminance, and prevent deterioration in the organic layers.

Abstract: The cathode for a gas discharged lamp includes gettering materials which are placed within the interior of the cathode shell. Other components may also be placed inside the cathode for continuous activation. For example, in mercury vapor lamps, a mercury amalgam is placed within the cathode. In another embodiment, a mass of electron emission assisting compound is placed within the cathode to replenish the emission assisting compound which deteriorates from the cathode.

Abstract: Fe--Ni alloys for electron gun parts consisting of, all by weight, 30-55% Ni, 0.0010-0.200% S, up to 0.8% Mn, from not less than 0.005 to less than 0.5% in total of one or more elements selected from the group consisting of Ti, Mg, Ce and Ca, and the balance substantially Fe and unavoidable impurities, and electron gun parts, typically electron gun electrodes, made of the alloys by punching are provided. Controlling the grain size number to No. 7.0 or above is also effective. The Fe--Ni alloys of this invention for electron gun parts are remarkably improved in press punchability and can solve burring problems through the easy formation of sulfide inclusions of Ti, Mg, Ce, and Ca.

Abstract: A cold cathode electrode for a discharge lamp has a metal substrate supporting a layer of diamond, so as to increase the electron yield of the electrode. The substrate may be a helical nickel wire with a layer of diamond forming it into a continuous tube.

Abstract: The invention relates to an electrode for discharge lamps, with an electron mitter which contains a barium compound from the group barium zirconate (BaZrO.sub.3), barium hafnate (BaHfO.sub.3), barium titanate (BaTiO.sub.3) and barium cerate (BaCeO.sub.3) as well as one or more metallic components.

Abstract: A planar fluorescent lamp employing both hot cathode and cold cathode operation is described. The lamp includes a first transparent cover bonded atop a metal body with a serpentine channel therein. The lamp body is coated with an insulative coating and the glass solder bead bonds the cover to the lamp at its perimeter and along the ridges defining the serpentine channel. An alternative embodiment of the lamp includes a second transparent cover bonded above the first transparent cover enabling the fluorescent material to be contained in a second enclosure, isolated from the source of light energy. A second alternative embodiment conceals the electrodes of the lamp beneath the lamp body and provides plasma slots to allow the concealed electrodes to energize the lamp. Another alternative embodiment utilizes a conductive transparent coating on the lamp cover to allow the lamp cover to supplement the lamp body as a cold cathode.

Abstract: Composite sintered electrodes with improved properties that make them suitable for use in a variety of lamp types, are provided which comprise a refractory metal and a substantial amount of a refractory emitter oxide, either single layer or multiple layer, the composites having been subjected to sintering at an elevated temperature effective to form a composite electrode having a density of at least 85%, preferably in the presence of a sintering activator, such as for example, Ni, or mixture thereof with a sintering aid such as, for example, Li.sub.2 O.

Abstract: A light transmitting discharge vessel encloses a discharge space, sealed in a gas-tight manner, in which electrodes connected to current conductors which extend to the exterior are disposed. A filling in the discharge vessel comprises a rare gas, a buffer gas and at least one transition metal halide chosen from the halides of hafnium, zirconium and tantalum. Each of the electrodes comprises an electrode part containing a carbide chosen from the carbides of hafnium, zirconium and tantalum. As a result diffusion of transition metal from the plasma into the electrode is strongly suppressed so that the lamp keeps very good color rendering properties throughout its operation.

Abstract: A lamp for emitting in the visible portion of the spectrum, which utilizes a fill which includes a selenium and/or a sulfur containing substance. The lamp has superior performance characteristics. Special electrode structures are provided which enhance longevity.

Abstract: An arc lamp having a sealed lamp tube with electrodes to either side of a septum. The septum extends through the length of the arc chamber. An emissions chamber extends from the end of the arc chamber without the septum. A window at the end of the emissions chamber is displaced from the end of the septum and from the arc chamber itself by a sufficient distance so that magnesium diffusing from the electrodes does not darken the surface. The magnesium electrodes are slugs encased within high temperature cells open at one end.

Abstract: The present invention is directed to new electrode structures for use in fluorescent lamps in which a tungsten base structure is provided with electron emissive materials including one or more of barium titanate, barium zirconate, barium strontium zirconate, barium cerium oxide, barium tantalate, and barium strontium yittrium oxide. Amounts of MgO may be added to improve or change emitter properties. A composite electrode structure can be formed by way of coating a tungsten coil with a slurry of this material, or providing powdered mixtures of both the electron emissive material and tungsten material and sintering this powdered material into a high density composite electrode structure.

Abstract: A passivated organic device including a transparent layer of conductive material formed on a supporting substrate. An active organic media formed on the transparent layer and an electrode formed on the active organic media, the electrode including a thin layer of lithium formed on the active organic media and a layer of indium overlying and passivating the layer of lithium, and completing the electrode.

Abstract: The invention concerns high-pressure discharge lamps, whose electrodes have a sintered compact (5) containing lanthanum oxide acting as an electron emitter, and this compact is surrounded by an electrode coil (6). Sintered compact (5) contains at least 90 weight % lanthanum oxide. In this way, a high thermal stability of sintered compact (5) and a good ignition performance of the lamp are assured with only negligible blackening of the discharge vessel over the service life of the lamp.

Abstract: A low-pressure discharge lamp according to the invention is provided with a radiation-transmitting discharge vessel which encloses a discharge space containing an ionizable filling in a gastight manner, and electrodes arranged in the discharge space between which a discharge path extends. At least one of the electrodes is a sintered mixture of metal and ceramic material, the proportional quantity of metal in the mixture being small compared with the proportional quantity of ceramic material. The sintered mixture includes smaller ceramic particles with a modal diameter D1 and larger ceramic particles with a modal diameter D2, the ratio D2/D1 being at least 3, while the proportional volume of the smaller ceramic particles is small compared with that of the larger ceramic particles. In the lamp according to the invention, the electrodes have a comparatively high resistance to temperature variations in spite of the small proportional volume of metal particles.

Abstract: The present invention relates to ion emitter tip metals and alloys for ionizing the molecules of a gas which concurrently produces small diameter and very low numbers of unwanted particles. Specifically, the invention discloses ion emitter tip materials which, when subjected to normal operating electrical conditions of between about 0.1 and 100 microamperes per emitter tip, produces about 1 particle or less having a diameter of about 0.5 microns or less per cubic foot. Useful ion emitter tip materials include zirconium, titanium, molybdenum, tantalum, rhenium or alloys of these metals. In a specific embodiment, the metal alloys comprise zirconium and rhenium, titanium and rhenium, molybdenum and rhenium, or tantalum and rhenium. Silicon coated metal emitter tips, particularly titanium-silicon coated are disclosed. The emitter tip materials are useful to obtain Class 1 clean room standards in static air or flowing air environments used, for example, in semiconductor manufacture.

Abstract: A fluorescent lamp device includes a transparent sealed container which is filled with a working gas, an electron emitting unit which extends into the container and which is operable to emit electrons that interact with the working gas to generate short-wave ultraviolet energy, and a light emitting member which is disposed in the container and which is made of an insulator material. The light emitting member has an external surface coated with a layer of fluorescent material that converts the ultraviolet energy into visible light.

Abstract: A fluorescent low pressure discharge lamp is provided with axially mounted cold-cathode electrodes consisting of a sintered shaped mixture of inorganic material including about 50-90% by weight of tungsten and the remainder BaO or a mixture of BaO, CaO and SrO and oxides of Y, Zr or Hf or the rare earths. The electrodes have a uniform density throughout with a porosity of less than 10%.

Abstract: An electron emitting, barium hafnate material for arc discharge lamp electrodes is manufactured by the method comprising the steps of: forming a mixture of barium carbonate and hafnium oxide in a 48 to 52 mole ratio; adding the mixture to a suitable carrier to form a slurry; ball milling the slurry for about 2 hours to form a powder mix; drying the powder mix; firing the dried powder mix in air at about 1500.degree. C. for about 22 hours to produce a product; and vibration milling the product in methanol with zirconia media to produce the barium hafnate. The latter material is then preferably vacuum impregnated into a tungsten electrode and hydrogen fired to produce a single phase barium oxide/hafnium oxide compound.

Abstract: The high-pressure metal halide discharge lamp has tungsten electrodes in a light-transmitting lamp vessel which is closed in a vacuumtight manner. The electrodes comprise an emitter which is distributed throughout their mass and is formed by a first oxide chosen from hafnium oxide and zirconium oxide and by a second oxide chosen from yttrium oxide, lanthanum oxide, cerium oxide and scandium oxide, and are substantially free from thorium oxide. The lamp retains its initial light output to a high degree throughout its life.

Abstract: A field emission element including a gate and an emitter and capable of preventing any of the element oxide layer from being formed on a tip of the emitter to prevent a decrease in emission current, unstable operation and an increase in noise. The gate has a surface formed of a material of oxygen bonding strength higher than that of a material for at least a tip surface of the emitter, so that oxygen atoms and molecules containing oxygen entering the gate may be captured by adsorption on the gate to prevent formation of any oxide layer on the emitter. When a portion of the emitter other than the tip surface is formed of a material of oxygen bonding strength higher than that of the material for the tip surface, formation of any oxide layer on the tip surface of the emitter is minimized.

Abstract: The present invention relates to ion emitter tip metals and alloys for ionizing the molecules of a gas which concurrently produces small diameter and very low numbers of unwanted particles. Specifically, the invention discloses ion emitter tip materials which, when subjected to normal operating electrical conditions of between about 0.1 and 100 microamperes per emitter tip, produces about 1 particle or less having a diameter of about 0.5 microns or less per cubic foot. Useful ion emitter tip materials include zirconium, titanium, molybdenum, tantalum, rhenium or alloys of these metals. In a specific embodiment, the metal alloys comprise zirconium and rhenium, titanium and rhenium, molybdenum and rhenium, or tantalum and rhenium. Silicon coated metal emitter tips, particularly titanium-silicon coated are disclosed. The emitter tip materials are useful to obtain Class 1 clean room standards in static air or flowing air environments used, for example, in semiconductor manufacture.

Abstract: A discharge element comprises a linear electrode and a sheet electrode both of which are provided opposite to each other with an insulator sheet therebetween, in which the linear electrode is formed by plasma spray coating a high-meting point semiconductor so as not to be worn when a high-frequency high voltage is applied between both electrodes.

Abstract: A gas discharge tube using a tunnel effect type electron emitting device as a cathode is provided. The electron emitting device comprises a conductive metal base and a dielectric film formed preferably of a material containing MgO as a main component on the metal base. The dielectric film faces an anode and is exposed to a gas in the tube. In the cathode of this structure, discharge is effected at a relatively low DC voltage.

Abstract: A high-power, high-repetition-rate spark gap switch having metal-hydride electrodes is provided The spark gap switch is configured with a trigger and two electrodes fabricated with metal hydrides. The hydride metals may be selected from a variety of alloys including iron, nickel, magnesium, and palladium based alloys. Use of these alloys for fabrication of the electrodes permits hydrogen to be absorbed into the electrode material at a density approximately that of liquid hydrogen. During operation of the switch, the increasing temperature causes hydrogen to be desorbed into cavity surrounding the switch. Whereas the increasing temperature lowers the breakdown voltage of the switch, the increasing pressure raises the breakdown voltage. The result is the switch operates at a constant breakdown voltage independent of temperature.

Abstract: A cathode for a laser generator includes a monolithic substrate consisting essentially of a nonconductive material and including a thin film of a conductive material deposited thereon. The substrate has an inner and outer surface, the thin film substantially contiguously covers the substrate and prevents exposure of the substrate over the life of the cathode, and the conductive thin film is oversprayed onto a portion of the substrate's outer surface so as to allow electrical contact from the outer surface to the inner surface.

Abstract: A cathode for a laser generator consists of a monolithic body consisting essentially of beryllium and beryllium oxide where the beryllium oxide has a concentration greater than 4%. The monolithic substrate may be comprised of a conductive or nonconductive material. A thin film of beryllium having a controlled amount of BeO is deposited onto the substrate so as to be thick enough to continuously cover the substrate and so as to prevent exposure of the substrate over the life of the cathode. The BeO content is greater than 4.0%. The BeO layer is deposited by a conventional thin film deposition method such as e-beam deposition, i-beam deposition, molecular beam epitaxy or other deposition processes. The BeO may advantageously be deposited using a Be target with a 4.0% BeO content, a Be target in an oxygen atmosphere, or a Be and a BeO target sputtered together.

Abstract: A fluorescent low pressure discharge lamp is provided with a sintered electrode consisting of about 50% to 90% by weight of W and the remainder BaO or a mixture of BaO, CaO and SrO and an oxide of Y, Zr, Hf or an oxide of the rare earths.

Abstract: A discharge electrode for a charger has a thin wire or core made of stainless steel or electrolytically polished tungsten, and a coating provided on the thin line. To form the coating, amorphous alloy containing tantalum, niobium, zirconium, titanium or similar element belonging to the same group on the periodic table is deposited on the thin wire by sputtering, CVD (Chemical Vapor Deposition) or similar technology. The content of tantalum in the amorphous alloy is selected to be 10 at % to 70 at %.

Abstract: To prevent the formation of melt-back slugs or granules on electrodes of h pressure, high power discharge lamps, when the lamps are operated under alternating current conditions of between about 20 to 60 A, for example, the electrodes are terminated in regions of decreasing diameter and, in accordance with the invention, comprise tungsten doped with lanthanum oxide (La.sub.2 O.sub.3) between about 0.5 to 2%, by weight, preferably about 1%. The doping intensity may increase towards the inside region of the electrode.

Abstract: A high-pressure metal vapor discharge lamp, for example and specifically a etal halide vapor discharge lamp, has a discharge vessel, in which electrodes are fitted from both ends, in form of an elongated ceramic hollow body, in which, in accordance with the invention, the ceramic is translucent, high-purity aluminum nitride (AIN). The end portions are closed off by closing electrodes in form of either solid pins or rods, from which electrode elements carried on shafts (13) extend, or a hollow tube (19) fitted into the end portion of the aluminum nitride discharge vessel and pinched and soldered shut. The solid or tubular closing elements can be inserted into a pre-sintered discharge vessel, preferably under inert atmospheric conditions, in a meticulously clean environment. For translucidness, the high-purity aluminum nitride should have less than 0.05% of metal cations, which may cause coloring or discoloration, less than 0.01% iron as two or three valent ions, and less than 0.

Abstract: A single side-sealed metal vapor discharge lamp is disclosed which includes a discharge tube having a sealed section at one end and a discharge region defining envelope at the other end, a pair of metal foils sealed at the sealed section and a pair of electrodes, the discharge region of the discharge tube containing a rare gas for starting and a filled gas containing mercury and light emitting metal. The electrodes are each comprised of a rod connected to the metal foil and a coil of at least one turn mounted on the forward end portion of a bent end portion of the rod, the coils being oppositely spaced apart by a predetermined distance in the discharge region. The coil is formed of a higher melting point material than a surface material of the forward end portion of the bent portion of the rod. With the length from the bent portion to the forward end of the rod indicated by L1, the length of the coil by L2 and the wire diameter of the coil by d, the following inequalities are satisfied: L1.ltoreq.3d and d/2.