Patent application number | Description | Published |
20080245408 | Method for manufacturing single-crystal silicon solar cell and single-crystal silicon solar cell - There is disclosed a method for manufacturing a single-crystal silicon solar cell including the steps of: implanting a hydrogen ion or a rare gas ion into a single-crystal silicon substrate; forming a transparent insulator layer on a metal substrate; performing a surface activation treatment with respect to at least one of the ion implanted surface and a surface of the transparent insulator layer; bonding these surfaces; mechanically delaminating the single-crystal silicon substrate to provide a single-crystal silicon layer; forming a plurality of second conductivity type diffusion regions in the delaminated surface side of the single-crystal silicon layer so that a plurality of first conductivity type regions and the plurality of second conductivity regions are present in the delaminated surface of the single-crystal silicon layer; respectively forming a plurality of individual electrodes on the plurality of first and second conductivity type regions of the single-crystal silicon layer; forming respective collecting electrodes; and forming a transparent protective film. | 10-09-2008 |
20080299376 | SILICON ON INSULATOR (SOI) WAFER AND PROCESS FOR PRODUCING SAME - Ion injection is performed to a single crystal silicon wafer to form an ion injection layer, with the ion injection surface of the single crystal silicon wafer and/or the surface of the transparent insulation substrate are/is processed using plasma and/or ozone. The ion injection surface of the single crystal silicon wafer and the surface of the transparent insulation substrate are bonded to each other by bringing them into close contact with each other at room temperature. A silicon on insulator (SOI) wafer is obtained by mechanically peeling the single crystal silicon wafer by giving an impact to the ion injection layer, to form an SOI layer on the transparent insulation substrate, and thermal processing for flattening the SOI layer surface is performed to the SOI wafer, under an atmosphere of an inert gas, a hydrogen gas, and a mixture gas of them. | 12-04-2008 |
20080305317 | SILICON ON INSULATOR (SOI) WAFER AND PROCESS FOR PRODUCING SAME - In a manufacturing method for manufacturing a silicon on insulator (SOI) wafer, an ion injection layer is formed within the wafer, by injecting a hydrogen ion or a rare gas ion from a surface of the single crystal silicon wafer, the ion injection surface of the single crystal silicon wafer and/or a surface of the transparent insulation substrate is processed using plasma and/or ozone, the ion injection surface of the single crystal silicon wafer is bonded to the surface of the transparent insulation substrate, by bringing them into close contact with each other at room temperature, with the processed surface(s) as bonding surface(s), and an SOI layer is formed on the transparent insulation substrate, by mechanically peeling the single crystal silicon wafer by giving an impact to the ion injection layer. | 12-11-2008 |
20080305318 | SILICON ON INSULATOR (SOI) WAFER AND PROCESS FOR PRODUCING SAME - In a manufacturing method of manufacturing a silicon on insulator (SOI) wafer, a single crystal silicon whose surface is an N region on an outer side of an OSF region, is grown and sliced to fabricate an N region single crystal silicon. An ion injection layer is formed within the N region single crystal silicon wafer by injecting a hydrogen ion or a rare gas ion from a surface of the N region single crystal silicon wafer; the ion injection surface of the N region single crystal silicon wafer and/or a surface of the transparent insulation substrate is processed using plasma and/or ozone. The ion injection surface is bonded to the surface of the transparent insulation substrate by bringing them into close contact with each other at room temperature. An SOI layer is formed by mechanically peeling the single crystal silicon wafer. | 12-11-2008 |
20090007960 | Method for manufacturing single crystal silicon solar cell and single crystal silicon solar cell - A method for manufacturing a single crystal silicon solar cell includes the steps of implanting either hydrogen ions or rare-gas ions into a single crystal silicon substrate; bringing the single crystal silicon substrate in close contact with a transparent insulator substrate via a transparent adhesive, with the ion-implanted surface being a bonding surface; curing the transparent adhesive; mechanically delaminating the single crystal silicon substrate to form a single crystal silicon layer; forming a plurality of diffusion areas of a second conductivity type in the delaminated surface side of the single crystal silicon layer, and causing a plurality of areas of a first conductivity type and the plurality of areas of the second conductivity type to be present in the delaminated surface of the single crystal silicon layer; forming each of a plurality of individual electrodes on each one of the plurality of areas of the first conductivity type and on each one of the plurality of areas of the second conductivity type in the single crystal silicon layer; forming a collector electrode for the plurality of individual electrodes on the plurality of areas of the first conductivity type, and a collector electrode for the plurality of individual electrodes on the plurality of areas of the second conductivity type; and forming a light-reflecting film. | 01-08-2009 |
20110003462 | METHOD FOR MANUFACTURING SOI WAFER - Provided is a method for manufacturing an SOI wafer, which is capable of: efficiently removing an ion-implanted defect layer existing in an ion implanted layer in the vicinity of a peeled surface peeled by an ion implantation peeling method; ensuring the in-plane uniformity of a substrate; and also achieving cost reduction and higher throughput. The method for manufacturing an SOI wafer includes at least the steps of: bonding a silicon wafer with or without an oxide film onto a handle wafer to prepare a bonded substrate, wherein the silicon wafer has an ion implanted layer formed by implanting hydrogen ions and/or rare gas ions into the silicon wafer; peeling the silicon wafer along the ion implanted layer, thereby transferring the silicon wafer onto the handle wafer to produce a post-peeling SOI wafer; immersing the post-peeling SOI wafer in an aqueous ammonia-hydrogen peroxide solution; and performing a heat treatment at a temperature of 900° C. or higher on the immersed post-peeling SOI wafer, and/or polishing a silicon film layer of the immersed post-peeling SOI wafer, through CMP polishing by 10 to 50 nm. | 01-06-2011 |
20110014776 | METHOD FOR PRODUCING SOI SUBSTRATE - A method for easily manufacturing a transparent SOI substrate having: a main surface with a silicon film formed thereon; and a rough main surface located on a side opposite to a side where the silicon film is formed. A method for manufacturing transparent SOI substrate, having a silicon film formed on a first main surface of the transparent insulating substrate, while a second main surface of the transparent insulating substrate, an opposite to the first main surface, is roughened. The method includes at least the steps of: roughening the first main surface with an RMS surface roughness lower than 0.7 nm and the second main surface with an RMS surface roughness higher than the surface roughness of the first main surface to prepare the transparent insulating substrate; and forming the silicon film on the first main surface of the transparent insulating substrate. | 01-20-2011 |
20110104871 | METHOD FOR MANUFACTURING BONDED SUBSTRATE - Provided is a method for manufacturing a bonded wafer with a good thin film over the entire substrate surface, especially in the vicinity of the lamination terminal point. The method for manufacturing a bonded wafer comprises at least the following steps of: forming an ion-implanted region by implanting a hydrogen ion or a rare gas ion, or the both types of ions from a surface of a first substrate which is a semiconductor substrate; subjecting at least one of an ion-implanted surface of the first substrate and a surface of a second substrate to be attached to a surface activation treatment; laminating the ion-implanted surface of the first substrate and the surface of the second substrate in an atmosphere with a humidity of 30% or less and/or a moisture content of 6 g/m | 05-05-2011 |
20110244655 | METHOD FOR FABRICATING SOI SUBSTRATE - There is provided a method for manufacturing an SOI substrate capable of effectively and efficiently embrittling an interface of an ion-implanted layer without causing the separation of a bonded surface | 10-06-2011 |
20120118354 | METHOD FOR MANUFACTURING SINGLE CRYSTAL SILICON SOLAR CELL AND SINGLE CRYSTAL SILICON SOLAR CELL - A single crystal silicon solar cell including a stack having at least a light-reflecting film, a single crystal silicon layer, a transparent adhesive layer, and a transparent insulator substrate; a plurality of areas of a first conductivity type and a plurality of areas of a second conductivity type formed in a surface of the silicon layer near the light-reflecting film; a plurality of pn junctions formed in a plane direction of the silicon layer; a plurality of first individual electrodes, each being formed on each one of the plurality of areas of the first conductivity type, and a plurality of second individual electrodes, each being formed on each one of the plurality of areas of the second conductivity type; and a first collector electrode for connecting the plurality of first individual electrodes and a second collector electrode for connecting the plurality of second individual electrodes. | 05-17-2012 |
20120119323 | SOS SUBSTRATE HAVING LOW SURFACE DEFECT DENSITY - A method of making bonded SOS substrate with a semiconductor film on or above a sapphire substrate by implanting ions from a surface of the semiconductor substrate to form an ion-implanted layer; activating at least a surface of one of the sapphire substrate and the semiconductor substrate from which the ions have been implanted; bonding the surface of the semiconductor substrate and the surface of the sapphire substrate at a temperature of from 50° C. to 350° C.; heating the bonded substrates at a maximum temperature of from 200° C. to 350° C.; and irradiating visible light from a sapphire substrate side or a semiconductor substrate side to the ion-implanted layer of the semiconductor substrate to make the interface of the ion-implanted layer brittle at a temperature of the bonded body higher than the temperature at which the surfaces were bonded, to transfer the semiconductor film to the sapphire substrate. | 05-17-2012 |
20120126362 | SOS SUBSTRATE HAVING LOW DEFECT DENSITY IN THE VICINITY OF INTERFACE - A bonded SOS substrate having a semiconductor film on or above a surface of a sapphire substrate is obtained by a method with the steps of implanting ions from a surface of a semiconductor substrate to form an ion-implanted layer; activating at least a surface from which the ions have been implanted; bonding the surface of the semiconductor substrate and the surface of the sapphire substrate at a temperature of 50° C. to 350° C.; heating the bonded substrates at a maximum temperature from 200° C. to 350° C. to form a bonded body; and irradiating visible light from a sapphire substrate side or a semiconductor substrate side to the ion-implanted layer of the semiconductor substrate for embrittling an interface of the ion-implanted layer, while keeping the bonded body at a temperature higher than the temperature at which the surfaces of the semiconductor substrate and the sapphire substrate were bonded. | 05-24-2012 |
20130309843 | SOS SUBSTRATE HAVING LOW DEFECT DENSITY IN VICINITY OF INTERFACE - A bonded SOS substrate having a semiconductor film on or above a surface of a sapphire substrate is obtained by a method with the steps of implanting ions from a surface of a semiconductor substrate to form an ion-implanted layer; activating at least a surface from which the ions have been implanted; bonding the surface of the semiconductor substrate and the surface of the sapphire substrate at a temperature of 50° C. to 350° C.; heating the bonded substrates at a maximum temperature from 200° C. to 350° C. to form a bonded body; and irradiating visible light from a sapphire substrate side or a semiconductor substrate side to the ion-implanted layer of the semiconductor substrate for embrittling an interface of the ion-implanted layer, while keeping the bonded body at a temperature higher than the temperature at which the surfaces of the semiconductor substrate and the sapphire substrate were bonded. | 11-21-2013 |
20140030870 | SOS SUBSTRATE HAVING LOW SURFACE DEFECT DENSITY - Method of making a bonded SOS substrate with a semiconductor film on or above a sapphire substrate by implanting ions from a surface of the semiconductor substrate to form an ion-implanted layer; activating at least a surface of one of the sapphire substrate and the semiconductor substrate from which the ions have been implanted; bonding the surface of the semiconductor substrate and the surface of the sapphire substrate at a temperature of from 50° C. to 350° C.; heating the bonded substrates at a maximum temperature of from 200° C. to 350° C.; and irradiating visible light from a sapphire substrate side or a semiconductor substrate side to the ion-implanted layer of the semiconductor substrate to make the interface of the ion-implanted layer brittle at a temperature of the bonded body higher than the temperature at which the surfaces were bonded, to transfer the semiconductor film to the sapphire substrate. | 01-30-2014 |