Patent application number | Description | Published |
20110115033 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - A semiconductor device which solves the following problem of a super junction structure: due to a relatively high concentration in the body cell region (active region), in peripheral areas (peripheral regions or junction end regions), it is difficult to achieve a breakdown voltage equivalent to or higher than in the cell region through a conventional junction edge terminal structure or resurf structure. The semiconductor device includes a power MOSFET having a super junction structure formed in the cell region by a trench fill technique. Also, super junction structures having orientations parallel to the sides of the cell region are provided in a drift region around the cell region. | 05-19-2011 |
20110284957 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - To fabricate a power MOSFET, etc. high in voltage-proofing (or breakdown voltage) and low in ON resistance (or On-state resistance) by a trench filling method, trial manufacture of power MOSFETs, etc. has been repeated with varying internal structures and layouts of super junction structures in a chip inner region located inside a guard ring. As a result, there occasionally occurred a source-drain voltage-proofing defect attributable to outer end portions of a supper junction structure. In one aspect of the present invention there is provided a semiconductor device having a power semiconductor element with a super junction structure introduced substantially throughout the whole surface of a drift region, the super junction structure being provided substantially throughout the whole surfaces of end portions of a semiconductor chip which configures the semiconductor device. | 11-24-2011 |
20110294278 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor device which prevents damage to alignment marks used for alignment between a superjunction structure and process layers at subsequent steps. In the related art, recesses are made in a semiconductor substrate before the formation of the superjunction structure and used as alignment marks and in order to prevent damage to the alignment marks, the alignment marks are covered by an insulating film such as a silicon oxide film during the subsequent process of forming the superjunction structure, but the inventors have found that damage may penetrate the cover film, reach the semiconductor substrate and destroy the marks. In the method according to the invention, alignment marks for alignment between the superjunction structure and process layers at subsequent steps are formed after the formation of the superjunction structure. | 12-01-2011 |
20130189819 | METHOD OF MANUFACTURING VERTICAL PLANAR POWER MOSFET AND METHOD OF MANUFACTURING TRENCH-GATE POWER MOSFET - In the manufacturing steps of a super-junction power MOSFET having a drift region having a super junction structure, after the super junction structure is formed, introduction of a body region and the like and heat treatment related thereto are typically performed. However, in the process thereof, a dopant in each of P-type column regions and the like included in the super junction structure is diffused to result in a scattered dopant profile. This causes problems such as degradation of a breakdown voltage when a reverse bias voltage is applied between a drain and a source and an increase in ON resistance. According to the present invention, in a method of manufacturing a silicon-based vertical planar power MOSFET, a body region forming a channel region is formed by selective epitaxial growth. | 07-25-2013 |
20130264650 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - A semiconductor device which solves the following problem of a super junction structure: due to a relatively high concentration in the body cell region (active region), in peripheral areas (peripheral regions or junction end regions), it is difficult to achieve a breakdown voltage equivalent to or higher than in the cell region through a conventional junction edge terminal structure or resurf structure. The semiconductor device includes a power MOSFET having a super junction structure formed in the cell region by a trench fill technique. Also, super junction structures having orientations parallel to the sides of the cell region are provided in a drift region around the cell region. | 10-10-2013 |
20140120669 | METHOD OF MANUFACTURING VERTICAL PLANAR POWER MOSFET AND METHOD OF MANUFACTURING TRENCH-GATE POWER MOSFET - In the manufacturing steps of a super-junction power MOSFET having a drift region having a super junction structure, after the super junction structure is formed, introduction of a body region and the like and heat treatment related thereto are typically performed. However, in the process thereof, a dopant in each of P-type column regions and the like included in the super junction structure is diffused to result in a scattered dopant profile. This causes problems such as degradation of a breakdown voltage when a reverse bias voltage is applied between a drain and a source and an increase in ON resistance. According to the present invention, in a method of manufacturing a silicon-based vertical planar power MOSFET, a body region forming a channel region is formed by selective epitaxial growth. | 05-01-2014 |
20140191309 | VERTICAL POWER MOSFET - When forming a super junction by the embedded epitaxial method, adjusting a taper angle of dry etching to form an inclined column is generally performed in trench forming etching, in order to prevent a reduction in breakdown voltage due to fluctuations in concentration in an embedded epitaxial layer. However, according to the examination by the present inventors, it has been made clear that such a method makes design more and more difficult in response to the higher breakdown voltage. In the present invention, the concentration in an intermediate substrate epitaxy column area in each substrate epitaxy column area configuring a super junction is made more than that in other areas within the substrate epitaxy column area, in a vertical power MOSFET having the super junction by the embedded epitaxial method. | 07-10-2014 |
20140206162 | MANUFACTURING METHOD OF POWER MOSFET USING A HARD MASK AS A STOP LAYER BETWEEN SEQUENTIAL CMP STEPS - A manufacturing method of a power MOSFET employs a hard mask film over a portion of the wafer surface as a polishing stopper, between two successive polishing steps. After embedded epitaxial growth is performed in a state where a hard mask film for forming trenches is present in at least a scribe region of a wafer, primary polishing is performed by using the hard mask film as a stopper, and secondary polishing is then performed after the hard mask film is removed. | 07-24-2014 |
20140284705 | METHOD OF MANUFACTURING VERTICAL PLANAR POWER MOSFET AND METHOD OF MANUFACTURING TRENCH-GATE POWER MOSFET - In the manufacturing steps of a super-junction power MOSFET having a drift region having a super junction structure, after the super junction structure is formed, introduction of a body region and the like and heat treatment related thereto are typically performed. However, in the process thereof, a dopant in each of P-type column regions and the like included in the super junction structure is diffused to result in a scattered dopant profile. This causes problems such as degradation of a breakdown voltage when a reverse bias voltage is applied between a drain and a source and an increase in ON resistance. According to the present invention, in a method of manufacturing a silicon-based vertical planar power MOSFET, a body region forming a channel region is formed by selective epitaxial growth. | 09-25-2014 |
20140299961 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - A semiconductor device which solves the following problem of a super junction structure: due to a relatively high concentration in the body cell region (active region), in peripheral areas (peripheral regions or junction end regions), it is difficult to achieve a breakdown voltage equivalent to or higher than in the cell region through a conventional junction edge terminal structure or resurf structure. The semiconductor device includes a power MOSFET having a super junction structure formed in the cell region by a trench fill technique. Also, super junction structures having orientations parallel to the sides of the cell region are provided in a drift region around the cell region. | 10-09-2014 |