| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 117099000 | With a chemical reaction (except ionization) in a disparate zone to form a precursor (e.g., transport processes) | 7 |
| 20090056619 | Halogen Assisted Physical Vapor Transport Method for Silicon Carbide Growth - A physical vapor transport growth technique for silicon carbide is disclosed. The method includes the steps of introducing a silicon carbide powder and a silicon carbide seed crystal into a physical vapor transport growth system, separately introducing a heated silicon-halogen gas composition into the system in an amount that is less than the stoichiometric amount of the silicon carbide source powder so that the silicon carbide source powder remains the stoichiometric dominant source for crystal growth, and heating the source powder, the gas composition, and the seed crystal in a manner that encourages physical vapor transport of both the powder species and the introduced silicon-halogen species to the seed crystal to promote bulk growth on the seed crystal. | 03-05-2009 |
| 20110155049 | MODERN HYDRIDE VAPOR-PHASE EPITAXY SYSTEM & METHODS - Hydride vapor-phase deposition (HVPE) systems are disclosed. An HVPE hydride vapor-phase deposition system may include a reactant source chamber and a growth chamber containing a susceptor coupled to the reactant source chamber. The reactant source chamber may be configured to create a reactant gas through a chemical reaction between a solid or liquid precursor and a different precursor gas. The reactant source chamber can be configured to operate at a temperature T(M) significantly above room temperature. The reactant gas can be chemically unstable at or near room temperature. The susceptor is configured to receive a substrate and maintain the substrate at a substrate temperature T(S). The growth chamber includes walls can be configured to operate at a temperature T(C) such that T(M), T(S) are greater than T(C). | 06-30-2011 |
| 20120247386 | METHOD AND APPARATUS FOR THE SELECTIVE DEPOSITION OF EPITAXIAL GERMANIUM STRESSOR ALLOYS - A method and apparatus for forming heterojunction stressor layers is described. A germanium precursor and a metal precursor are provided to a chamber, and an epitaxial layer of germanium-metal alloy formed on the substrate. The metal precursor is typically a metal halide, which may be provided by subliming a solid metal halide or by contacting a pure metal with a halogen gas. The precursors may be provided through a showerhead or through a side entry point, and an exhaust system coupled to the chamber may be separately heated to manage condensation of exhaust components. | 10-04-2012 |
| 20120291698 | METHODS FOR IMPROVED GROWTH OF GROUP III NITRIDE SEMICONDUCTOR COMPOUNDS - Methods are disclosed for growing group III-nitride semiconductor compounds with advanced buffer layer technique. In an embodiment, a method includes providing a suitable substrate in a processing chamber of a hydride vapor phase epitaxy processing system. The method includes forming an AlN buffer layer by flowing an ammonia gas into a growth zone of the processing chamber, flowing an aluminum halide containing precursor to the growth zone and at the same time flowing additional hydrogen halide or halogen gas into the growth zone of the processing chamber. The additional hydrogen halide or halogen gas that is flowed into the growth zone during buffer layer deposition suppresses homogeneous AlN particle formation. The hydrogen halide or halogen gas may continue flowing for a time period while the flow of the aluminum halide containing precursor is turned off. | 11-22-2012 |
| 20130247817 | METAL CHLORIDE GAS GENERATOR, HYDRIDE VAPOR PHASE EPITAXY GROWTH APPARATUS, AND METHOD FOR FABRICATING A NITRIDE SEMICONDUCTOR TEMPLATE - A metal chloride gas generator includes a reactor including a receiving section for receiving a metal on an upstream side and a growing section in which a growth substrate is placed on a downstream side, a raw material section heater and a growing section heater each of which heats an inside of the reactor, an upstream end comprising a gas inlet, and a gas inlet pipe arranged to extend from the upstream end via the receiving section to the growing section, for introducing a chloride gas from the upstream end to supply the chloride gas to the receiving section and supplying a metal chloride gas produced by a reaction between the chloride gas and the metal in the receiving section to the growing section. The gas inlet pipe includes a suppressing section for suppressing an optical waveguiding phenomenon which waveguides a radiant heat from the growing section heater or the growing section. | 09-26-2013 |
| 20130319320 | Production Method of an Aluminum Based Group III Nitride Single Crystal - A production method of aluminum based group III nitride single crystal includes a reaction step, wherein a halogenated gas and an aluminum contact at 300° C. or more to 700° C. or less, producing a mixed gas including an aluminum trihalide gas and an aluminum monohalide gas; a converting step, wherein the aluminum monohalide gas is converted to a solid by setting a temperature of the mixed gas equal to or higher than a temperature to which a solid aluminum trihalide deposit, and lower by 50° C. or more than a temperature to which halogenated gas and aluminum contact in the reaction step; a separation step, wherein the aluminum trihalide gas is removed; and a crystal growth step, wherein the aluminum trihalide gas is used for an aluminum based group III nitride single crystal raw material, keeping its temperature equal to or higher than a temperature of the converting step. | 12-05-2013 |
| 20160060789 | Silicon Carbide Crystal Growth by Silicon Chemical Vapor Transport - In a method for growing bulk SiC single crystals using chemical vapor transport, wherein silicon acts as a chemical transport agent for carbon, a growth crucible is charged with a solid carbon source material and a SiC single crystal seed disposed therein in spaced relationship. A halosilane gas, such as SiCl | 03-03-2016 |
