Entries |
Document | Title | Date |
20080315775 | Electron Emission Device Using Abrupt Metal-Insulator Transition and Display Including the Same - An electron emission device having a high electron emitting rate and a display including the device are prodivided. The electron emission device using abrupt metal-insulator transition, the device including: a board; a metal-insulator transition (MIT) material layer disposed on the board and divided by a predetermined gap with portions of the divided MIT material layer facing one another; and electrodes connected to each of the portions of the divided metal-insulator transition material layer for emitting electrons to the gap between the portions of the divided metal-insulator transition material layer. | 12-25-2008 |
20100194295 | Field Emission Device - The present invention relates to a field emission device. More specifically, the present invention may prohibit unnecessary voltage from being applied to an anode electrode during non-operating time that no voltage is applied to a gate electrode to reduce driving power, prohibit electrons from being emitted with unnecessary high voltage which is applied to the anode electrode to increase luminous efficiency, and reduce a time that unnecessary high voltage is applied to the anode electrode to extend life time of the field emission device, by applying AC voltage to the anode electrode to correspond to a time that voltage is applied to the gate electrode and a type of voltage which is applied to the gate electrode. Therefore, the present invention comprises a front substrate and a rear substrate which are disposed at a certain distance and opposite to each other; at least one or more cathode electrodes formed on said rear substrate; at least one or more gate electrodes formed to be distant from said cathode electrodes and to be insulated with said rear substrate; emitters formed on the upper surfaces of said cathode electrodes; an anode electrode formed on said front substrate toward said rear substrate side; a fluorescent layer formed on said anode electrode; a first voltage application means for applying an AC voltage to said anode electrode; and a second voltage application means for applying an AC voltage to said gate electrode, wherein the AC voltages being applied to said anode electrode and said gate electrode are synchronized. | 08-05-2010 |
20100244710 | Organic Luminescence Transistor Device and Manufacturing Method Thereof - Disclosed is an organic light-emitting transistor device comprising a substrate, a first electrode layer formed on the upper side of the substrate, a multilayer structure formed locally on the upper side of the first electrode layer in a predetermined size and sequentially having an insulating layer, an auxiliary electrode layer and a charge injection-suppressing layer in this order, an organic EL layer formed on the upper side of the first electrode layer where at least the multilayer structure is not formed, and a second electrode layer formed on the upper side of the organic EL layer. This organic light-emitting transistor device is characterized in that the charge injection-suppressing layer is formed larger than the auxiliary electrode when viewed in plan. | 09-30-2010 |
20100289413 | ELECTRON INJECTION-CONTROLLED MICROCAVITY PLASMA DEVICE AND ARRAYS - An embodiment of the invention is a microcavity plasma device that can be controlled by a low voltage electron emitter. The microcavity plasma device includes driving electrodes disposed proximate to a microcavity and arranged to contribute to generation of plasma in the microcavity upon application of a driving voltage. An electron emitter is arranged to emit electrons into the microcavity upon application of a control voltage. The electron emitter is an electron source having an insulator layer defining a tunneling region. The microplasma itself can serve as a second electrode necessary to energize the electron emitter. While a voltage comparable to previous microcavity plasma devices is still imposed across the microcavity plasma devices, control of the devices can be accomplished at high speeds and with a small voltage, e.g., about 5V to 30V in preferred embodiments. | 11-18-2010 |
20110148310 | FIELD EMISSION LAMP - Provided is a field emission lamp (FEL), which includes a plurality of cathode electrodes formed above a first substrate, an anode electrode formed under a second substrate to face the cathode electrode, a fluorescent layer composed of red, green and blue (RGB) patterns formed alternately on the anode electrode in an oblique direction, and a plurality of emitters formed on the cathode electrodes to correspond to the RGB patterns. According to the present invention, as an FEL having a fast response time is used as a backlight unit, a color breaking phenomenon can be prevented in a color sequential driving method. | 06-23-2011 |
20140333213 | FIELD EMISSION DEVICE WITH AC OUTPUT - A field emission device is configured as a heat engine with an AC output. | 11-13-2014 |
20150097491 | Light bulb and florescent tube replacement using FIPEL panels - A lighting device formed of a FIPEL panel driven by electrical connection. For example, a frequency generator can create a frequency that creates a light output having any frequency in the spectrum. The light emitting panel can be flexible, and can be coded along a curved surface, such as the inner surface of a light bulb. | 04-09-2015 |
20160013009 | VARIABLE FIELD EMISSION DEVICE | 01-14-2016 |