Patent application number | Description | Published |
20080233664 | Semiconductor integrated circuit production method and device - A semiconductor integrated circuit production method prepares an SOI layer thickness database that correlates measurement data of each SOI layer thickness with each SOI substrate identification data. The production method extracts the measurement data for each SOI substrate from the SOI layer thickness database, and carries out layer thickness adjustment surface treatment for the SOI substrates based on these data. A semiconductor integrated circuit production device includes an SOI layer thickness database storage unit for storing the SOI layer thickness database, and a layer thickness adjustment conditions control unit for extracting the measurement data for each SOI substrate from the SOI layer thickness database and deciding conditions for the layer thickness adjustment surface treatment based on these data. The semiconductor integrated circuit production device also includes a surface treatment unit that adjusts SOI layer thickness by carrying out the surface treatment on the SOI layers in accordance with the decided conditions. | 09-25-2008 |
20090317950 | METHOD OF MANUFACTURING SEMICONDUCTOR DEVICE - A semiconductor device manufacturing method which sequentially forms a gate oxide film and gate electrode material over a semiconductor layer of an SOI substrate and patterns the material into gate electrodes. The method further comprises the steps of forming sidewalls made of an insulator to cover side surfaces of the gate electrode; ion-implanting into the semiconductor layer on both sides of the gate electrode to form drain/source regions; partially etching the sidewalls to expose upper parts of the side surfaces of the gate electrode; depositing a metal film to cover the tops of the drain/source regions and of the gate electrode and the exposed upper parts of the side surfaces of the gate electrode; and performing heat treatment on the SOI substrate to form silicide layers respectively in the surfaces of the gate electrode and of the drain/source regions. | 12-24-2009 |
20100244135 | Semiconductor device - In a semiconductor device of a silicon on insulator (SOI) structure having uniform transistor properties, a first distance between a gate electrode forming position of an N type transistor and an end of a P type semiconductor region is greater than a second distance between a gate electrode forming position of the P type transistor and an edge of the N type semiconductor region. | 09-30-2010 |
20100248410 | Method of fabricating semiconductor device - There is provided a method of fabricating a semiconductor device having plural light receiving elements, and having an amplifying element, the method including: a) forming an active region on the semiconductor substrate for configuring the amplifying element; b) forming a light receiving element region on the semiconductor substrate for forming the plural light receiving elements, with the active region acting as a reference for positioning; c) implanting an impurity into the light receiving element region; d) repeating the process b) and the process c) a number of times that equals a number of diffusion layers in the light receiving element region; e) after implanting the impurity, performing a drive-in process to carry out drive in of the semiconductor substrate; and f) the process e), forming an amplifying element forming process by implanting an impurity in the active region. | 09-30-2010 |
20110101458 | SOI type semiconductor device having a protection circuit - An SOI type semiconductor device having a silicon substrate and a buried oxide layer formed on the silicon substrate includes an internal circuit formed in a first region having at least one FD type transistor having a SOI structure, the internal circuit performing a function of the semiconductor device and a protection circuit formed in a second region having at least one PD type transistor having a SOI structure, the protection circuit protecting the internal circuit from electro static damage. | 05-05-2011 |
20110117741 | Method of fabricating SOI wafer - There is provided a method of fabricating an SOI wafer, the method including: a) preparing a bonded SOI substrate that has a buried oxide layer and an SOI layer formed in this sequence on a circular plate shaped support, and at a peripheral edge portion of the support substrate, has a silicon island region in which the SOI layer is not well formed with scattered defective silicon layer; b) etching a silicon island region defective silicon layer to remove the defective silicon layer scattered in the silicon island region by dry etching; and c) etching a silicon island region buried oxide layer to remove the buried oxide layer in the silicon island region by wet etching. | 05-19-2011 |
20110204444 | Semiconductor intergrated device and method of manufacturing same - A semiconductor integrated device of the invention can enhance a radiation resistance. In an exemplary embodiment, the semiconductor integrated device includes a semiconductor supporting substrate, an insulation layer provided on the semiconductor supporting substrate, and a silicon thin film provided on the insulation layer. A predetermined region in the silicon thin film that is adjacent to the boundary between the insulation layer and the silicon thin film (i.e., boundary neighboring region) has an impurity-concentration-increased region. In this region, the impurity concentration becomes higher as the position approaches the boundary. | 08-25-2011 |
Patent application number | Description | Published |
20080237769 | SEMICONDUCTOR OPTICAL SENSOR - A sensor includes a substrate provided with a circuit element forming region and a photodiode forming region, the substrate having a silicon substrate, an insulating layer on the silicon substrate, and a silicon layer on the insulating layer; a photodiode in the silicon layer; a circuit element in the silicon layer; a first interlayer insulating film formed over the silicon layer; a first light-shielding film on the first interlayer film and having an opening in the photodiode forming region; and a first inter-region light-shielding plug arranged between the two regions, for connecting the silicon substrate and the first light-shielding film. | 10-02-2008 |
20080237801 | Semiconductor device - A semiconductor device includes a resistor element formed in a semiconductor layer of an SOI substrate (Silicon On Insulator). The semiconductor device includes a low concentration impurity area formed in the semiconductor layer as the resistor element; a high concentration impurity area formed in the semiconductor layer as a resistor element wiring portion; and a silicide layer selectively formed on the high concentration impurity area. The high concentration impurity area includes one end portion contacting with an end portion of the low concentration impurity area, and the other end portion contacting with an impurity area of another element. | 10-02-2008 |
20090078880 | Ultraviolet sensor - An ultraviolet sensor has an ultraviolet detection diode having a depletion region | 03-26-2009 |
20120193714 | SOI SUBSTRATE, METHOD OF MANUFACTURING THE SOI SUBSTRATE, SEMICONDUCTOR DEVICE, AND METHOD OF MANUFACTURING THE SEMICONDUCTOR DEVICE - Disclosed is an SOI substrate which includes a semiconductor base; a semiconductor layer formed over the semiconductor base; and a buried insulating film which is disposed between the semiconductor base and the semiconductor layer, so as to electrically isolate the semiconductor layer from the semiconductor base, where the buried insulating film contains a nitride film. | 08-02-2012 |
20130043537 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - There is provided a semiconductor device and a method for manufacturing a semiconductor device. Within the N-type semiconductor layer formed from a high resistance N-type substrate, the P-type well diffusion layer and P-type extraction layer are formed and are fixed to ground potential. Due thereto, a depletion layer spreading on the P-type well diffusion layer side does not reach the interlayer boundary between the P-type well diffusion layer and the buried oxide film. Hence, the potential around the surface of the P-type well diffusion layer is kept at a ground potential. Accordingly, when the voltages are applied to the backside of the N-type semiconductor layer and a cathode electrode, a channel region at the MOS-type semiconductor formed as a P-type semiconductor layer is not activated. Due thereto, leakage current that may occur independently of a control due to the gate electrode of a transistor can be suppressed. | 02-21-2013 |