Abstract: Disclosed is a method and system applicable to attaching a single or multiple optical fibers in sequence to a photonic integrated circuit enabling precise control of optical fibers and/or multiple types of optical fibers and/or at any pitch. The system and method provide optical alignment and in situ attachment of one or more optical fibers to a photonic integrated circuit chip using a photo-curable adhesive, wherein curing light is delivered to the adhesive by the optical fiber being attached.

Abstract: Systems, devices and methods useful for aligning and attaching optical fibers and optical fiber ribbons to a photonic integrated circuit.

Abstract: A method of making a display having a plurality of spaced apart organic light-emitting diodes devices (OLEDs) that have serially connected electrodes for providing a lighting display wherein each one of the OLED devices is spaced apart from the next OLED device.

Abstract: A method for tensioning a shadow mask includes positioning a first side of a shadow mask into contact with the lower half of a tensioning frame, positioning an upper half of the tensioning frame into contact with a second side of the shadow mask, and clamping the upper half of the tensioning frame to the lower half of the tensioning frame to form a tensioning frame, and rigidly clamping the shadow mask between the two tensioning frame halves. The method also includes elevating the temperature of the tensioning frame to tension the shadow mask.

Abstract: A method of aligning an OLED substrate with a shadow mask includes forming a shadow mask with at least three spaced alignment openings, providing a precision alignment element into each of the alignment openings, and positioning the OLED substrate so that the edges of the OLED substrate engage the precision alignment elements and thereby align the shadow mask with the OLED substrate.

Abstract: A method for metering powdered or granular material onto a heated surface to vaporize such material. The method comprises providing a rotatable auger d for receiving powdered or granular material and as the rotatable auger rotates, such rotatable auger translates such powdered or granular material along a feed path to a feeding location. The method also providing at least one opening at the feeding location such that the pressure produced by the rotating rotatable auger at the feeding location causes the powdered or granular material to be forced through the opening onto the heated surface in a controllable manner. The material is agitated or fluidized proximate to the feeding location.

Abstract: A method for the vaporization of particulate material includes providing one or more containers each containing possibly distinct particulate materials each having at least one component, fluidizing the particulate material in at least one of the containers, and providing a vaporization zone that is thermally isolated from at least one of the containers. The method further includes delivering particulate material received from each container to the vaporization zone, and applying heat to vaporize the delivered particulate materials at the vaporization zone.

Abstract: A method for metering powdered or granular material onto a heated surface to vaporize such material, includes providing a container with powdered or granular material having at least one component; providing a rotatable auger disposed in material receiving relationship with the container for receiving powdered or granular material from the container and as the auger rotates, such rotating auger translates such powdered or granular material along a feed path to a feeding location; and providing at least one opening at the feeding location such that the pressure produced by the rotating auger at the feeding location causes the powdered or granular material to be forced through the opening onto the heated surface in a controllable manner.

Abstract: Apparatus for vaporization of powdered material, includes one or more containers each containing possibly distinct powdered materials each having at least one component; a structure for fluidizing the powdered material in each container; a vaporization zone that is thermally isolated from at least one of the containers; a transporting structure for receiving fluidized powdered material from each container and delivering such fluidized powdered materials to the vaporization zone; and vaporizing the delivered powdered materials at the vaporization zone by applying heat.

Abstract: A method for hermetically sealing an organic thin-film light-emitting device between a substrate and a cover comprising the steps of bringing the substrate and cover into close proximity at a peripheral side edge of at least one of the substrate or cover, bringing an energy absorbing material into contact with the cover and substrate at the peripheral side edge of at least one of the substrate or cover, and applying energy directly to the energy absorbing material, causing the energy absorbing material to transfer heat to the substrate and the cover to fuse and form a hermetic seal along the peripheral side edge.

Abstract: A method for controlling the deposition of vaporized organic material onto a substrate surface, includes providing a heating device to produce vaporized organic material; providing a manifold having at least one aperture through which vaporized organic material passes for deposition onto the substrate surface; providing a controller operating independently of the heating device and effective in a first condition for limiting the passage of vaporized organic material through the aperture, and effective in a second condition for facilitating the passage of vaporized organic material through the aperture; and wherein the heating device, or the controller, or both are contiguous to the manifold.

Abstract: A method for controlling the deposition of vaporized organic material onto a substrate surface, includes providing a manifold having at least one aperture through which vaporized organic material passes for deposition onto the substrate surface; and providing a volume of organic material and maintaining the temperature of such organic material in a first condition so that its vapor pressure is below that needed to effectively form a layer on the substrate, and in a second condition heating a volume percentage of the initial volume of such organic material so that the vapor pressure of the heated organic material is sufficient to effectively form a layer.