Patent application number | Description | Published |
20080210959 | Light emitting apparatus - In order to provide light emitting devices which have simple constructions and thus can be fabricated easily, and can stably provide high light emission efficiencies for a long time period, a light emitting device includes an n-type nitride semiconductor layer at a first main surface side of a nitride semiconductor substrate, a p-type nitride semiconductor layer placed more distantly from the nitride semiconductor substrate than the n-type nitride semiconductor layer at the first main surface side and a light emitting layer placed between the n-type nitride semiconductor layer and the p-type nitride semiconductor layer at the first main surface side. The nitride semiconductor substrate has a resistivity of 0.5 Ω·cm or less and the p-type nitride semiconductor layer side is down-mounted so that light is emitted from the second main surface of the nitride semiconductor substrate at the opposite side from the first main surface. | 09-04-2008 |
20080217745 | Nitride Semiconductor Wafer - A nitride semiconductor substrate having properties preferable for the manufacture of various nitride semiconductor devices is made available, by specifying or controlling the local variation in the off-axis angle of the principal surface of the nitride semiconductor substrate. The substrate, being misoriented, is manufactured to have an off-axis angle distribution across its principal surface such that variation Δθ in the off-axis angle is continuous within a predetermined angular range. | 09-11-2008 |
20080296585 | GROWTH METHOD OF GaN CRYSTAL, AND GaN CRYSTAL SUBSTRATE - A method of producing a GaN crystal is directed to growing a GaN crystal on a GaN seed crystal substrate. The method includes the steps of preparing a GaN seed crystal substrate including a first dopant such that the thermal expansion coefficient of the GaN seed crystal substrate becomes greater than that of the GaN crystal, and growing the GaN crystal to a thickness of at least 1 mm on the GaN seed crystal substrate. Accordingly, there can be provided a method of producing a GaN crystal that can suppress generation of a crack and grow a thick GaN crystal, and a GaN crystal substrate. | 12-04-2008 |
20080299748 | Group III-V Crystal - Favorable-quality III-V crystals are easily obtained at low cost without causing cracks, even when using a variety of substrates. The III-V crystals are obtained by manufacturing method characterized in including: a step of depositing a metal film ( | 12-04-2008 |
20090071394 | AlxInyGa1-x-yN MIXTURE CRYSTAL SUBSTRATE, METHOD OF GROWING AlxInyGa1-x-yN MIXTURE CRYSTAL SUBSTRATE AND METHOD OF PRODUCING AlxInyGa1-x-yN MIXTURE CRYSTAL SUBSTRATE - A low dislocation density Al | 03-19-2009 |
20090236694 | Method of Manufacturing III-Nitride Crystal, and Semiconductor Device Utilizing the Crystal - The present III-nitride crystal manufacturing method, a method of manufacturing a III-nitride crystal ( | 09-24-2009 |
20090315149 | MANUFACTURING METHOD OF NITRIDE SUBSTRATE, NITRIDE SUBSTRATE, AND NITRIDE-BASED SEMICONDUCTOR DEVICE - A manufacturing method of a nitride substrate includes the steps of preparing a ground substrate; forming a mask on the ground substrate; placing the ground substrate in a reactor, and heating the ground substrate to a temperature of 850° C. to 1100° C. In the step of heating the ground substrate, HCl and NH3 are supplied into the reactor so that partial pressure P | 12-24-2009 |
20100009526 | FABRICATION METHOD AND FABRICATION APPARATUS OF GROUP III NITRIDE CRYSTAL SUBSTANCE - A fabrication method of a group III nitride crystal substance includes the steps of cleaning the interior of a reaction chamber by introducing HCl gas into the reaction chamber, and vapor deposition of a group III nitride crystal substance in the cleaned reaction chamber. A fabrication apparatus of a group III nitride crystal substance includes a configuration to introduce HCl gas into the reaction chamber, and a configuration to grow a group III nitride crystal substance by HVPE. Thus, a fabrication method of a group III nitride crystal substance including the method of effectively cleaning deposits adhering inside the reaction chamber during crystal growth, and a fabrication apparatus employed in the fabrication method are provided. | 01-14-2010 |
20100090313 | III-V Compound Crystal and Semiconductor Electronic Circuit Element - Favorable-quality III-V crystals are easily obtained at low cost without causing cracks, even when using a variety of substrates, and can be used to manufacture semiconductor devices with good quality and at high yields. The III-V crystals are characterized by the following properties: the carrier concentration, resistivity, and dislocation density of the III-V compound crystal are uniform to within ±30% variation along the surface; the III-V compound crystal is misoriented from the c-plane such that the crystal surface does not include any region where its off-axis angle with the c-plane is 0°; and the full width at half-maximum in XRD at the crystal center of the III-V compound is not greater than 150 arcsec. | 04-15-2010 |
20100139553 | Method of Growing III-Nitride Crystal - Affords a method of growing, across the entirety of a major surface of a first III-nitride crystal, a second III-nitride crystal by HVPE, in an ambient temperature higher than 1100° C. The present III-nitride crystal growth method comprises: a step of preparing a first III-nitride crystal ( | 06-10-2010 |
20100155902 | Manufacturing Method of Nitride Substrate, Nitride Substrate, and Nitride-Based Semiconductor Device - A manufacturing method of a nitride substrate includes the steps of: preparing a ground substrate; forming a mask on the ground substrate; placing the ground substrate in a reactor, and heating the ground substrate to a temperature of 850° C. to 1100° C. In the step of heating the ground substrate, HCl and NH | 06-24-2010 |
20100189624 | GROUP III NITRIDE CRYSTAL AND METHOD OF ITS GROWTH - Affords group III nitride crystal growth methods enabling crystal to be grown in bulk by a liquid-phase technique. One such method of growing group III nitride crystal from solution is provided with: a step of preparing a substrate having a principal face and including at least on its principal-face side a group III nitride seed crystal having the same chemical composition as the group III nitride crystal, and whose average density of threading dislocations along the principal face being 5×10 | 07-29-2010 |
20100207138 | III Nitride Semiconductor Crystal, III Nitride Semiconductor Device, and Light Emitting Device - Group III nitride semiconductor crystals of a size appropriate for semiconductor devices and methods for manufacturing the same, Group III nitride semiconductor devices and methods for manufacturing the same, and light-emitting appliances. A method of manufacturing a Group III nitride semiconductor crystal includes a process of growing at least one Group III nitride semiconductor crystal substrate on a starting substrate, a process of growing at least one Group III nitride semiconductor crystal layer on the Group III nitride semiconductor crystal substrate, and a process of separating a Group III nitride semiconductor crystal, constituted by the Group III nitride semiconductor crystal substrate and the Group III nitride semiconductor crystal layer, from the starting substrate, and is characterized in that the Group III nitride semiconductor crystal is 10 μm or more but 600 μm or less in thickness, and is 0.2 mm or more but 50 mm or less in width. | 08-19-2010 |
20100229786 | Method for Growing Group III Nitride Crystal - A III-nitride crystal growth method that enables growing large-scale crystal under a liquid-phase technique is made available. The present III-nitride crystal growth method is a method of growing III-nitride crystal ( | 09-16-2010 |
20110057197 | GaN SINGLE CRYSTAL SUBSTRATE AND METHOD OF MANUFACTURING THEREOF AND GaN-BASED SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THEREOF - A GaN single crystal substrate has a main surface with an area of not less than 10 cm | 03-10-2011 |
20110065265 | FABRICATION METHOD AND FABRICATION APPARATUS OF GROUP III NITRIDE CRYSTAL SUBSTANCE - A fabrication method of a group III nitride crystal substance includes the steps of cleaning the interior of a reaction chamber by introducing HCl gas into the reaction chamber, and vapor deposition of a group III nitride crystal substance in the cleaned reaction chamber. A fabrication apparatus of a group III nitride crystal substance includes a configuration to introduce HCl gas into the reaction chamber, and a configuration to grow a group III nitride crystal substance by HVPE. Thus, a fabrication method of a group III nitride crystal substance including the method of effectively cleaning deposits adhering inside the reaction chamber during crystal growth, and a fabrication apparatus employed in the fabrication method are provided. | 03-17-2011 |
20110108852 | GaN SUBSTRATE AND LIGHT-EMITTING DEVICE - The present GaN substrate can have an absorption coefficient not lower than 7 cm | 05-12-2011 |
20110260295 | III-Nitride Crystal Substrate and III-Nitride Semiconductor Device - Affords methods of manufacturing bulk III-nitride crystals whereby at least the surface dislocation density is low globally. The present III-nitride crystal manufacturing method includes: a step of preparing an undersubstrate ( | 10-27-2011 |
20120031324 | METHOD FOR GROWING GROUP III NITRIDE CRYSTAL - The present invention is to provide a method for growing a group III nitride crystal that has a large size and has a small number of pits formed in the main surface of the crystal by using a plurality of tile substrates. A method for growing a group III nitride crystal includes a step of preparing a plurality of tile substrates | 02-09-2012 |
20120034149 | GaN-CRYSTAL FREE-STANDING SUBSTRATE AND METHOD FOR PRODUCING THE SAME - The invention relates to a GaN-crystal free-standing substrate obtained from a GaN crystal grown by HVPE with a (0001) plane serving as a crystal growth plane and at least one plane of a {10-11} plane and a {11-22} plane serving as a crystal growth plane that constitutes a facet crystal region, except for the side surface of the crystal, wherein the (0001)-plane-growth crystal region has a carbon concentration of 5×10 | 02-09-2012 |
20120034763 | Method of Manufacturing Nitride Semiconductor Substrate - The present invention provides a method of manufacturing a nitride semiconductor substrate capable of efficiently manufacturing a nitride semiconductor substrate having a nonpolar plane as a major surface in which polycrystalline growth is minimized. A method of manufacturing a GaN substrate, which is a nitride semiconductor substrate, includes steps (S | 02-09-2012 |
20120074403 | METHOD FOR GROWING GaN CRYSTAL AND GaN CRYSTAL SUBSTRATE - The present invention is to provide GaN crystal growing method for growing a GaN crystal with few stacking faults on a GaN seed crystal substrate having a main surface inclined at an angle of 20° to 90° from the (0001) plane, and also to provide a GaN crystal substrate with few stacking faults. A method for growing a GaN crystal includes the steps of preparing a GaN seed crystal substrate | 03-29-2012 |
20120118222 | METHOD OF MANUFACTURING GaN-BASED FILM - A method of manufacturing a GaN-based film includes the steps of preparing a composite substrate, the composite substrate including a support substrate in which a coefficient of thermal expansion in its main surface is more than 1.0 time and less than 1.2 times as high as a coefficient of thermal expansion of GaN crystal in a direction of a axis and a single crystal film arranged on a main surface side of the support substrate, the single crystal film having threefold symmetry with respect to an axis perpendicular to a main surface of the single crystal film, and forming a GaN-based film on the main surface of the single crystal film in the composite substrate, the single crystal film in the composite substrate being an SiC film. Thus, a method of manufacturing a GaN-based film capable of manufacturing a GaN-based film having a large main surface area and less warpage is provided. | 05-17-2012 |
20120122301 | METHOD OF MANUFACTURING GaN-BASED FILM - A method of manufacturing a GaN-based film includes the steps of preparing a composite substrate, the composite substrate including a support substrate in which a coefficient of thermal expansion in its main surface is more than 0.8 time and less than 1.0 time as high as a coefficient of thermal expansion of GaN crystal in a direction of a axis and a single crystal film arranged on a main surface side of the support substrate, the single crystal film having threefold symmetry with respect to an axis perpendicular to a main surface of the single crystal film, and forming a GaN-based film on the main surface of the single crystal film in the composite substrate, the single crystal film in the composite substrate being an SiC film. Thus, a method of manufacturing a GaN-based film capable of manufacturing a GaN-based film having a large main surface area and less warpage without crack being produced in a substrate is provided. | 05-17-2012 |
20120142168 | III-V Compound Crystal and Semiconductor Electronic Circuit Element - Favorable-quality III-V crystals are easily obtained at low cost without causing cracks, even when using a variety of substrates, and can be used to manufacture semiconductor devices with good quality and at high yields. The III-V crystals are characterized by the following properties: the carrier concentration, resistivity, and dislocation density of the III-V compound crystal are uniform to within ±30% variation along the surface; the III-V compound crystal is misoriented from the c-plane such that the crystal surface does not include any region where its off-axis angle with the c-plane is 0°; and the full width at half-maximum in XRD at the crystal center of the III-V compound is not greater than 150 arcsec. | 06-07-2012 |
20120164058 | METHOD FOR MANUFACTURING GALLIUM NITRIDE CRYSTAL AND GALLIUM NITRIDE WAFER - There is provided a method for fabricating a gallium nitride crystal with low dislocation density, high crystallinity, and resistance to cracking during polishing of sliced pieces by growing the gallium nitride crystal using a gallium nitride substrate including dislocation-concentrated regions or inverted-polarity regions as a seed crystal substrate. Growing a gallium nitride crystal | 06-28-2012 |
20120228612 | COMPOSITE BASE INCLUDING SINTERED BASE AND BASE SURFACE FLATTENING LAYER, AND COMPOSITE SUBSTRATE INCLUDING THAT COMPOSITE BASE AND SEMICONDUCTOR CRYSTALLINE LAYER - A composite base of the present invention includes a sintered base and a base surface flattening layer disposed on the sintered base, and the base surface flattening layer has a surface RMS roughness of not more than | 09-13-2012 |
20120228613 | METHOD OF MANUFACTURING SEMICONDUCTOR WAFER, AND COMPOSITE BASE AND COMPOSITE SUBSTRATE FOR USE IN THAT METHOD - A method of manufacturing a semiconductor wafer of the present invention includes the steps of: obtaining a composite base by forming a base surface flattening layer having a surface RMS roughness of not more than 1.0 nm on a base; obtaining a composite substrate by attaching a semiconductor crystal layer to a side of the composite base where the base surface flattening layer is located; growing at least one semiconductor layer on the semiconductor crystal layer of the composite substrate; and obtaining the semiconductor wafer including the semiconductor crystal layer and the semiconductor layer by removing the base surface flattening layer by wet etching and thereby separating the semiconductor crystal layer from the base. Thus, a method of manufacturing a semiconductor wafer capable of efficiently manufacturing the semiconductor wafer regardless of the type of a base, and a composite base and a composite substrate suitably used in that manufacturing method are provided to efficiently manufacture a semiconductor device. | 09-13-2012 |
20120315445 | Group-III Nitride Crystal Composite - III-nitride crystal composites are made up of especially processed crystal slices cut from III-nitride bulk crystal having, ordinarily, a {0001} major surface and disposed adjoining each other sideways, and of III-nitride crystal epitaxially on the bulk-crystal slices. The slices are arranged in such a way that their major surfaces parallel each other, but are not necessarily flush with each other, and so that the [0001] directions in the slices are oriented in the same way. | 12-13-2012 |
20120329245 | Group III Nitride Crystal and Method for Producing the Same - A method for producing a group III nitride crystal in the present invention includes the steps of cutting a plurality of group III nitride crystal substrates | 12-27-2012 |
20130040442 | METHOD OF MANUFACTURING GaN-BASED FILM - The present method of manufacturing a GaN-based film includes the steps of preparing a composite substrate, the composite substrate including a support substrate in which a coefficient of thermal expansion in a main surface is more than 0.8 time and less than 1.2 times as high as a coefficient of thermal expansion of GaN crystal in a direction of a axis and a single crystal film arranged on a side of the main surface of the support substrate, the single crystal film having threefold symmetry with respect to an axis perpendicular to a main surface of the single crystal film, and forming a GaN-based film on the main surface of the single crystal film in the composite substrate. Thus, a method of manufacturing a GaN-based film capable of manufacturing a GaN-based film having a large main surface area and less warpage is provided. | 02-14-2013 |
20130149847 | METHOD OF MANUFACTURING GaN-BASED FILM AND COMPOSITE SUBSTRATE USED THEREFOR - The present method of manufacturing a GaN-based film includes the steps of preparing a composite substrate including a support substrate dissoluble in hydrofluoric acid and a single crystal film arranged on a side of a main surface of the support substrate, a coefficient of thermal expansion in the main surface of the support substrate being more than 0.8 time and less than 1.2 times as high as a coefficient of thermal expansion of GaN crystal, forming a GaN-based film on a main surface of the single crystal film arranged on the side of the main surface of the support substrate, and removing the support substrate by dissolving the support substrate in hydrofluoric acid. Thus, the method of manufacturing a GaN-based film capable of efficiently obtaining a GaN-based film having a large main surface area, less warpage, and good crystallinity, as well as a composite substrate used therefor are provided. | 06-13-2013 |
20130160699 | Method of Manufacturing III-Nitride Crystal - Provided is a method of manufacturing III-nitride crystal having a major surface of plane orientation other than {0001}, designated by choice, the III-nitride crystal manufacturing method including: a step of slicing III-nitride bulk crystal through a plurality of planes defining a predetermined slice thickness in the direction of the designated plane orientation, to produce a plurality of III-nitride crystal substrates having a major surface of the designated plane orientation; a step of disposing the substrates adjoining each other sideways in a manner such that the major surfaces of the substrates parallel each other and such that any difference in slice thickness between two adjoining III-nitride crystal substrates is not greater than 0.1 mm; and a step of growing III-nitride crystal onto the major surfaces of the substrates. | 06-27-2013 |
20130244406 | FABRICATION METHOD AND FABRICATION APPARATUS OF GROUP III NITRIDE CRYSTAL SUBSTANCE - A fabrication method of a group III nitride crystal substance includes the steps of cleaning the interior of a reaction chamber by introducing HCl gas into the reaction chamber, and vapor deposition of a group III nitride crystal substance in the cleaned reaction chamber. A fabrication apparatus of a group III nitride crystal substance includes a configuration to introduce HCl gas into the reaction chamber, and a configuration to grow a group III nitride crystal substance by HVPE. Thus, a fabrication method of a group III nitride crystal substance including the method of effectively cleaning deposits adhering inside the reaction chamber during crystal growth, and a fabrication apparatus employed in the fabrication method are provided. | 09-19-2013 |
20130337632 | Method for Producing Group III Nitride Crystal - A method for producing a Group III nitride crystal includes the steps of cutting a plurality of Group III nitride crystal substrates | 12-19-2013 |
20140061668 | GaN Single Crystal Substrate and Method of Manufacturing Thereof and GaN-based Semiconductor Device and Method of Manufacturing Thereof - A GaN single crystal substrate has a main surface with an area of not less than 10 cm | 03-06-2014 |
20140175616 | Composite of III-Nitride Crystal on Laterally Stacked Substrates - Group-III nitride crystal composites made up of especially processed crystal slices, cut from III-nitride bulk crystal, whose major surfaces are of {1-10±2}, {11-2±2}, {20-2±1} or {22-4±1} orientation, disposed adjoining each other sideways with the major-surface side of each slice facing up, and III-nitride crystal epitaxially present on the major surfaces of the adjoining slices, with the III-nitride crystal containing, as principal impurities, either silicon atoms or oxygen atoms. | 06-26-2014 |
20140369920 | Group III Nitride Crystal Substrates and Group III Nitride Crystal - Group III nitride crystal produced by cutting, from III nitride bulk crystal, a plurality of Group III nitride crystal substrates with major-surface plane orientation misoriented five degrees or less with respect to a crystal-geometrically equivalent plane orientation selected from the group consisting of {20-21}, {20-2-1}, {22-41}, and {22-4-1}, transversely arranging the substrates adjacent to each other such that their major surfaces are parallel to each other and such that their [0001] directions coincide with each other, and growing a Group III nitride crystal on the major surfaces. The Group III nitride crystal substrates are further characterized by satisfying at least either an oxygen-atom concentration of 1×10 | 12-18-2014 |