Patent application number | Description | Published |
20080258218 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - A MIS transistor having an inclined stacked source/drain structure increased in speed is provided. The MIS transistor comprises: a gate electrode formed on a substrate; a first sidewall insulating film formed on the substrate and along a sidewall of the gate electrode; source/drain semiconductor regions formed on a main surface of the substrate and respectively having one edge positioned under the sidewall of the gate electrode; a first stacked layer formed on the source/drain semiconductor regions and in contact with the first sidewall insulating film; a second sidewall insulating film formed on the stacked layer and in contact with the first sidewall insulating film; and a second stacked layer formed on the first stacked layer and in contact with the second sidewall insulating layer. | 10-23-2008 |
20090057746 | SEMICONDUCTOR DEVICE - A semiconductor device having a passive element whose characteristic is adjustable even after manufacture by applying back bias voltage is provided. Formed on a main surface of a SOI substrate comprising a supporting substrate, a BOX layer, and an SOI layer is a MOS varactor comprising a gate dielectric formed on a surface of the SOI layer, a gate electrode formed on the gate dielectric, and a n | 03-05-2009 |
20090096036 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - There is provided an SOI-MISFET including: an SOI layer; a gate electrode provided on the SOI layer interposing a gate insulator; and a first elevated layer provided higher in height from the SOI layer than the gate electrode at both sidewall sides of the gate electrode on the SOI layer so as to constitute a source and drain. Further, there is also provided a bulk-MISFET including: a gate electrode provided on a silicon substrate interposing a gate insulator thicker than the gate insulator of the SOI MISFET; and a second elevated layer configuring a source and drain provided on a semiconductor substrate at both sidewalls of the gate electrode. A the first elevated layer is thicker than the elevated layer, and the whole of the gate electrodes, part of the source and drain of the SOI-MISFET, and part of the source and drain of the bulk-MISFET are silicided. | 04-16-2009 |
20090101977 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - An object of the present invention is to provide a semiconductor device having a fin-type transistor that is excellent in characteristics by forming a fin-shaped semiconductor portion and a gate electrode with high precision or by making improvement regarding variations in characteristics among elements. The present invention is a semiconductor device including a fin-shaped semiconductor portion having a source region formed on one side thereof and a drain region formed on the other side thereof, and a gate electrode formed between the source region and the drain region to surround the fin-shaped semiconductor portion with a gate insulating film interposed therebetween. One solution for solving the problem according to the invention is that the gate electrode uses a metal material or a silicide material that is wet etchable. | 04-23-2009 |
20090134468 | SEMICONDUCTOR DEVICE AND METHOD FOR CONTROLLING SEMICONDUCTOR DEVICE - To provide a semiconductor device having a thin-film BOX-SOI structure and capable of realizing a high-speed operation of a logic circuit and a stable operation of a memory circuit. A semiconductor device according to the present invention includes a semiconductor support substrate, an insulation layer having a thickness of at mast 10 nm, and a semiconductor layer. In an upper surface of the semiconductor layer, a first field-effect transistor including a first gate electrode and constituting a logic circuit is formed. Further, in the upper surface of the semiconductor layer, a second field-effect transistor including a second gate electrode and constituting a memory circuit is formed. At least three well regions having different conductivity types are formed in the semiconductor support substrate. In the presence of the well regions, a region of the semiconductor support substrate below the first gate electrode and a region of the semiconductor support substrate below the second gate electrode are electrically separated from each other. | 05-28-2009 |
20090309159 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD OF THE SAME - Performance of a semiconductor device having a MIS transistor is improved. A semiconductor device includes: a pair of source/drain regions each formed by stacking a semiconductor layer on a main surface of a silicon substrate; a sidewall insulating film covering each sidewall of the source/drain regions; a gate electrode arranged so as to interpose a gate insulating film on the main surface of the silicon substrate at a position sandwiched by the sidewall insulating films in a plane; and extension regions formed to extend from a portion below and lateral to the gate electrode to a portion below and lateral to each of the source/drain regions, wherein a sidewall of the sidewall insulating film being adjacent to the gate insulating film and the gate electrode has an inclination of a forward tapered shape. | 12-17-2009 |
20100084709 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING SAME - When a bulk silicon substrate and an SOI substrate are used separately, a board area is increased and so it is impossible to reduce the size of a semiconductor device as a whole. On the other hand, when an SOI-type MISFET and a bulk-type MISFET are formed on a same substrate, the SOI-type MISFET and the bulk-type MISFET should be formed in separate steps respectively, and thus the process gets complicated. A single crystal semiconductor substrate and an SOI substrate separated from the single crystal semiconductor substrate by a thin buried insulating film and having a thin single crystal semiconductor thin film (SOI layer) are used, and well diffusion layer regions, drain regions, gate insulating films and gate electrodes of the SOI-type MISFET and the bulk-type MISFET are formed in same steps. Since the bulk-type MISFET and the SOI-type MISFET can be formed on the same substrate, the board area can be reduced. A simple process can be realized by making manufacturing steps of the SOI-type MISFET and the bulk-type MISFET common. | 04-08-2010 |
20100258869 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - An n well and a p well disposed at a predetermined interval on a main surface of a SOI substrate with a thin BOX layer are formed, and an nMIS formed on the p well has a pair of n-type source/drain regions formed on semiconductor layers stacked on a main surface of the SOI layer at a predetermined distance, a gate insulating film, a gate electrode and sidewalls sandwiched between the pair of n-type source/drain regions. A device isolation is formed between the n well and the p well, and a side edge portion of the device isolation extends toward a gate electrode side more than a side edge portion of the n-type source/drain region (sidewall of the BOX layer). | 10-14-2010 |
20100258871 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - Characteristics of a semiconductor device having a FINFET are improved. The FINFET has: a channel layer arranged in an arch shape on a semiconductor substrate and formed of monocrystalline silicon; a front gate electrode formed on a part of an outside of the channel layer through a front gate insulating film; and a back gate electrode formed so as to be buried inside the channel layer through a back gate insulating film. The back gate electrode arranged inside the arch shape is arranged so as to pass through the front gate electrode. | 10-14-2010 |
20100258872 | SEMICONDUCTOR DEVICE - A technique to be applied to a semiconductor device for achieving low power consumption by improving a shape at a boundary portion of a shallow trench and an SOI layer of an SOI substrate. A position (SOI edge) at which a main surface of a silicon substrate and a line extended along a side surface of an SOI layer are crossed is recessed away from a shallow-trench isolation more than a position (STI edge) at which a line extended along a sidewall of a shallow trench and a line extended along the main surface of the silicon substrate are crossed, and a corner of the silicon substrate at the STI edge has a curved surface. | 10-14-2010 |
20110195566 | METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE - There is provided an SOI-MISFET including: an SOI layer; a gate electrode provided on the SOI layer interposing a gate insulator; and a first elevated layer provided higher in height from the SOI layer than the gate electrode at both sidewall sides of the gate electrode on the SOI layer so as to constitute a source and drain. Further, there is also provided a bulk-MISFET including: a gate electrode provided on a silicon substrate interposing a gate insulator thicker than the gate insulator of the SOI MISFET; and a second elevated layer configuring a source and drain provided on a semiconductor substrate at both sidewalls of the gate electrode. A the first elevated layer is thicker than the elevated layer, and the whole of the gate electrodes, part of the source and drain of the SOI-MISFET, and part of the source and drain of the bulk-MISFET are silicided. | 08-11-2011 |
20120018807 | SEMICONDUCTOR DEVICE, METHOD FOR MANUFACTURING SAME, AND SEMICONDUCTOR STORAGE DEVICE - In an SOI-MISFET that operates with low power consumption at a high speed, an element area is reduced. While a diffusion layer region of an N-conductivity type MISFET region of the SOI type MISFET and a diffusion layer region of a P-conductivity type MISFET region of the SOI type MISFET are formed as a common region, well diffusion layers that apply substrate potentials to the N-conductivity type MISFET region and the P-conductivity type MISFET region are separated from each other by an STI layer. The diffusion layer regions that are located in the N- and P-conductivity type MISFET regions) and serve as an output portion of a CMISFET are formed as a common region and directly connected by silicified metal so that the element area is reduced. | 01-26-2012 |
20120061774 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD OF THE SAME - Performance of a semiconductor device having a MIS transistor is improved. A semiconductor device includes: a pair of source/drain regions each formed by stacking a semiconductor layer on a main surface of a silicon substrate; a sidewall insulating film covering each sidewall of the source/drain regions; a gate electrode arranged so as to interpose a gate insulating film on the main surface of the silicon substrate at a position sandwiched by the sidewall insulating films in a plane; and extension regions formed to extend from a portion below and lateral to the gate electrode to a portion below and lateral to each of the source/drain regions, wherein a sidewall of the sidewall insulating film being adjacent to the gate insulating film and the gate electrode has an inclination of a forward tapered shape. | 03-15-2012 |
20120149143 | Method for Manufacturing a Solar Cell - In the existent method for manufacturing a solar cell, manufacture of a solar cell having a quantum well having a crystalline well layer and capable of controlling the thickness of the well layer was difficult. A quantum well having an amorphous well layer, comprising a barrier layer and an amorphous well layer is formed and then the quantum well having the amorphous well layer is annealed thereby crystallizing the amorphous well layer to form a quantum well having a crystalline well layer. By applying energy density applied to the amorphous well layer at an energy density of 1.26 J/mm | 06-14-2012 |
20120196411 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING SAME - A device and a method for manufacturing the same in which with device includes a single crystal semiconductor substrate and an SOI substrate separated from the single crystal semiconductor substrate by a thin buried insulating film and having a thin single crystal semiconductor thin film (SOI layer) in which well diffusion layer regions, drain regions, gate insulating films, and gate electrodes of the SOI-type MISFET and the bulk-type MISFET are formed in the same steps. The bulk-type MISFET and the SOI-type MISFET are formed on the same substrate, so that board area is reduced and a simple process can be realized by making manufacturing steps of the SOI-type MISFET and the bulk-type MISFET common. | 08-02-2012 |
20120309157 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - An object of the present invention is to provide a semiconductor device having a fin-type transistor that is excellent in characteristics by forming a fin-shaped semiconductor portion and a gate electrode with high precision or by making improvement regarding variations in characteristics among elements. The present invention is a semiconductor device including a fin-shaped semiconductor portion having a source region formed on one side thereof and a drain region formed on the other side thereof, and a gate electrode formed between the source region and the drain region to surround the fin-shaped semiconductor portion with a gate insulating film interposed therebetween. One solution for solving the problem according to the invention is that the gate electrode uses a metal material or a silicide material that is wet etchable. | 12-06-2012 |
20120318337 | Solar Cell - In a conventional solar cell, it has been difficult to ensure a sufficient light absorption and simultaneously to prevent current loss due to the reduction of the moving distance of electrons and holes. As a means for solving this difficulty, a plurality of a p-i-n junctions are stacked through an insulating film and are connected in parallel with each other using through-electrodes. In this case, the through-electrodes and the p-i-n junctions are connected through the p-layer or the n-layer, thereby moving electrons and holes in opposite directions and generating output current. In addition, the i-layer is made thicker than the p-layer and the n-layer in each of the p-i-n junctions, thereby ensuring a sufficient light absorption and simultaneously preventing current loss. | 12-20-2012 |
20130105812 | SEMICONDUCTOR DEVICE | 05-02-2013 |
20130146897 | 4h-SiC SEMICONDUCTOR ELEMENT AND SEMICONDUCTOR DEVICE - A trench groove is formed and a silicon oxide film is buried in the periphery of a channel region of (0001) surface 4h-SiC semiconductor element. The oxide film in the trench groove is defined in such a planar layout that a tensile strain is applied along the direction of the c-axis and a compressive strain is applied along two or more of axes on a plane perpendicular to the c-axis. For example, trench grooves buried with an oxide film may be configured to such a layout that they are in a trigonal shape surrounding the channel, or are arranged symmetrically with respect to the channel as a center when arranged discretely. | 06-13-2013 |
20130240991 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING SAME - A device and a method for manufacturing the same in which with device includes a single crystal semiconductor substrate and an SOI substrate separated from the single crystal semiconductor substrate by a thin buried insulating film and having a thin single crystal semiconductor thin film (SOI layer), in which well diffusion layer regions, drain regions, gate insulating films, and gate electrodes of the SOI-type MISFET and the bulk-type MISFET are formed in the same steps. The bulk-type MISFET and the SOI-type MISFET are formed on the same substrate, so that board area is reduced and a simple process can be realized by making manufacturing steps of the SOI-type MISFET and the bulk-type MISFET common. | 09-19-2013 |
20140166100 | SOLAR CELL - A solar cell including a substrate | 06-19-2014 |
20150053261 | SOLAR CELL - A surface reflectivity of a solar cell is reduced by applying a nanopillar array including a plurality of nanopillars to the solar cell. Further, by constituting the nanopillars with a Si/SiGe superlattice and controlling a Ge composition ratio of a SiGe layer ( | 02-26-2015 |