Abstract: A method of manufacturing a semiconductor device that includes a semiconductor layer of a first conductivity type, and a parallel pn layer formed on the semiconductor layer, the pn layer having first semiconductor regions of the first conductivity type and second semiconductor regions of a second conductivity type, the first and second regions being alternately arranged parallel to a surface of the semiconductor layer. In one embodiment, the method includes repeatedly performing the following steps to stack the epitaxial growth layers on the semiconductor layer to form the pn layer: forming an epitaxial growth layer of the first conductivity type or non-doped, the epitaxial growth layer having an impurity concentration lower than that of the semiconductor layer, ion implanting a first-conductivity-type impurity into the epitaxial growth layer, selectively ion implanting a second-conductivity-type impurity into the epitaxial growth layer and ion implanting a group 18 element into the epitaxial growth layer.

Abstract: A method of manufacturing a semiconductor device that includes a semiconductor layer of a first conductivity type, and a parallel pn layer formed on the semiconductor layer, the pn layer having first semiconductor regions of the first conductivity type and second semiconductor regions of a second conductivity type, the first and second regions being alternately arranged parallel to a surface of the semiconductor layer. In one embodiment, the method includes repeatedly performing the following steps to stack the epitaxial growth layers on the semiconductor layer to form the pn layer: forming an epitaxial growth layer of the first conductivity type or non-doped, the epitaxial growth layer having an impurity concentration lower than that of the semiconductor layer, ion implanting a first-conductivity-type impurity into the epitaxial growth layer, selectively ion implanting a second-conductivity-type impurity into the epitaxial growth layer and ion implanting a group 18 element into the epitaxial growth layer.

Abstract: A first parallel pn layer having a first n-type region and a first p-type region junctioned alternately and repeatedly is disposed in an element active portion. The first parallel pn layer has a striped planar layout. A second parallel pn layer having a second n-type region and a second p-type region junctioned alternately and repeatedly is disposed in a high voltage structure. The second parallel pn layer has a striped planar layout in a direction identical to that of the first parallel pn layer. An intermediate region having a third parallel pn layer and a fourth parallel pn layer of a lower impurity quantity than the first parallel pn layer is disposed between the first and second parallel pn layers, and formed by diffusing impurity implanting regions becoming the first and the second parallel pn layers formed separated from each other to a region in which no impurity is ion-implanted.

Abstract: A semiconductor device, including a semiconductor layer of a first conductivity type, and a parallel pn layer formed on a surface of the semiconductor layer. The parallel pn layer includes a plurality of first semiconductor regions of the first conductivity type, and a plurality of second semiconductor regions of a second conductivity type. The first and second semiconductor regions are alternatingly arranged in a direction parallel to the surface of the semiconductor layer. Each second semiconductor region has at least one first region that is a region having a group 18 element introduced therein.

Abstract: A semiconductor device with a high radiation tolerance is provided. A semiconductor device comprising a semiconductor substrate, a first body region and a second body region provided on a front surface side of the semiconductor substrate, a neck portion provided between the first body region and the second body region, a first source region formed within the first body region and a second source region formed within the second body region, a first gate electrode provided to face the first body region between the first source region and the neck portion, a second gate electrode provided to face the second body region between the second source region and the neck portion, and an insulating film continuously provided between the first gate electrode and the semiconductor substrate, between the second gate electrode and the semiconductor substrate, and on the front surface side of the neck portion, is provided.

Abstract: A SJ-MOSFET includes a parallel pn layer in which an n-type drift region and a p-type partition region are alternately arranged repeatedly along a direction parallel to a base main-surface. The n-type drift region and the p-type partition region have total impurity amounts that are roughly the same and widths that are basically constant over an entire depth direction. The n-type drift region is configured to have an n-type impurity concentration profile in which an impurity concentration of a portion on the drain-side is higher than an impurity concentration of a portion on the source-side by ?Cnx. The p-type partition region is configured to have a p-type impurity concentration profile in which an impurity concentration of a portion on the drain-side is higher than an impurity concentration of a portion on the source-side by ?Cph, and an impurity concentration of part of the portion on the source-side is relatively low.

Abstract: A perpendicular type of magnetic recording medium has a multi-layered recording structure made up of a plurality of ferro-magnetic layers and a non-magnetic layer interposed between the plurality of ferro-magnetic layers, and the perpendicular magnetic anisotropy energy of the lower ferro-magnetic layer is greater than the perpendicular magnetic anisotropy energy of the upper ferro-magnetic layer. Accordingly, the lower ferro-magnetic layer may be easily magnetically reversed by a magnetic field applied during a write operation. Thus, the perpendicular type of magnetic recording medium exhibits an enhanced thermal stability and write-ability.

Abstract: A first parallel pn layer in which first n-type regions and first p-type regions are disposed in a plan view layout of stripes in an element active portion. A second parallel pn layer has a plan view layout of stripes oriented in the same direction as that of the stripes of the first parallel pn layer in a breakdown voltage structure portion. Corner portions of the first parallel pn layer has a plan view shape where stepped regions formed by shortening the length of the first n-type and p-type regions in steps are disposed in a stepwise arrangement. The stepped regions continue with a second parallel pn layer via an intermediate region lower in average impurity concentration than the first parallel pn layer.

Abstract: A first parallel pn layer in which first n-type regions and first p-type regions are disposed in a plan view layout of stripes in an element active portion. A second parallel pn layer has a plan view layout of stripes oriented in the same direction as that of the stripes of the first parallel pn layer in a breakdown voltage structure portion. Corner portions of the first parallel pn layer has a plan view shape where stepped regions formed by shortening the length of the first n-type and p-type regions in steps are disposed in a stepwise arrangement. The stepped regions continue with a second parallel pn layer via an intermediate region lower in average impurity concentration than the first parallel pn layer.

Abstract: A first parallel pn layer having a first n-type region and a first p-type region junctioned alternately and repeatedly is disposed in an element active portion. The first parallel pn layer has a striped planar layout. A second parallel pn layer having a second n-type region and a second p-type region junctioned alternately and repeatedly is disposed in a high voltage structure. The second parallel pn layer has a striped planar layout in a direction identical to that of the first parallel pn layer. An intermediate region having a third parallel pn layer and a fourth parallel pn layer of a lower impurity quantity than the first parallel pn layer is disposed between the first and second parallel pn layers, and formed by diffusing impurity implanting regions becoming the first and the second parallel pn layers formed separated from each other to a region in which no impurity is ion-implanted.

Abstract: A SJ-MOSFET includes a parallel pn layer in which an n-type drift region and a p-type partition region are alternately arranged repeatedly along a direction parallel to a base main-surface. The n-type drift region and the p-type partition region have total impurity amounts that are roughly the same and widths that are basically constant over an entire depth direction. The n-type drift region is configured to have an n-type impurity concentration profile in which an impurity concentration of a portion on the drain-side is higher than an impurity concentration of a portion on the source-side by ?Cnx. The p-type partition region is configured to have a p-type impurity concentration profile in which an impurity concentration of a portion on the drain-side is higher than an impurity concentration of a portion on the source-side by ?Cph, and an impurity concentration of part of the portion on the source-side is relatively low.

Abstract: A semiconductor device, including a semiconductor layer of a first conductivity type, and a parallel pn layer formed on a surface of the semiconductor layer. The parallel pn layer includes a plurality of first semiconductor regions of the first conductivity type, and a plurality of second semiconductor regions of a second conductivity type. The first and second semiconductor regions are alternatingly arranged in a direction parallel to the surface of the semiconductor layer. Each second semiconductor region has at least one first region that is a region having a group 18 element introduced therein.

Abstract: A first parallel pn layer in which first n-type regions and first p-type regions are disposed in a plan view layout of stripes in an element active portion. A second parallel pn layer has a plan view layout of stripes oriented in the same direction as that of the stripes of the first parallel pn layer in a breakdown voltage structure portion. Corner portions of the first parallel pn layer has a plan view shape where stepped regions formed by shortening the length of the first n-type and p-type regions in steps are disposed in a stepwise arrangement. The stepped regions continue with a second parallel pn layer via an intermediate region lower in average impurity concentration than the first parallel pn layer.

Abstract: A first parallel pn layer having a first n-type region and a first p-type region junctioned alternately and repeatedly is disposed in an element active portion. The first parallel pn layer has a striped planar layout. A second parallel pn layer having a second n-type region and a second p-type region junctioned alternately and repeatedly is disposed in a high voltage structure. The second parallel pn layer has a striped planar layout in a direction identical to that of the first parallel pn layer. An intermediate region having a third parallel pn layer and a fourth parallel pn layer of a lower impurity quantity than the first parallel pn layer is disposed between the first and second parallel pn layers, and formed by diffusing impurity implanting regions becoming the first and the second parallel pn layers formed separated from each other to a region in which no impurity is ion-implanted.

Abstract: A semiconductor device with a high radiation tolerance is provided. A semiconductor device comprising a semiconductor substrate, a first body region and a second body region provided on a front surface side of the semiconductor substrate, a neck portion provided between the first body region and the second body region, a first source region formed within the first body region and a second source region formed within the second body region, a first gate electrode provided to face the first body region between the first source region and the neck portion, a second gate electrode provided to face the second body region between the second source region and the neck portion, and an insulating film continuously provided between the first gate electrode and the semiconductor substrate, between the second gate electrode and the semiconductor substrate, and on the front surface side of the neck portion, is provided.

Abstract: A semiconductor device with a high radiation tolerance is provided. A semiconductor device comprising a semiconductor substrate, a first body region and a second body region provided on a front surface side of the semiconductor substrate, a neck portion provided between the first body region and the second body region, a first source region formed within the first body region and a second source region formed within the second body region, a first gate electrode provided to face the first body region between the first source region and the neck portion, a second gate electrode provided to face the second body region between the second source region and the neck portion, and an insulating film continuously provided between the first gate electrode and the semiconductor substrate, between the second gate electrode and the semiconductor substrate, and on the front surface side of the neck portion, is provided.

Abstract: A perpendicular magnetic recording medium exhibits reduced noise and improved performance in such measures as SN ratio, and can realize high magnetic recording densities. In the perpendicular magnetic recording medium, at least a first nonmagnetic intermediate layer, second nonmagnetic intermediate layer, and magnetic recording layer are stacked in order on a nonmagnetic substrate. The first nonmagnetic intermediate layer is formed from a CoCrRuW alloy, and the second nonmagnetic intermediate layer is formed from an Ru-base alloy.

Abstract: A semiconductor device with a high radiation tolerance is provided. A semiconductor device comprising a semiconductor substrate, a first body region and a second body region provided on a front surface side of the semiconductor substrate, a neck portion provided between the first body region and the second body region, a first source region formed within the first body region and a second source region formed within the second body region, a first gate electrode provided to face the first body region between the first source region and the neck portion, a second gate electrode provided to face the second body region between the second source region and the neck portion, and an insulating film continuously provided between the first gate electrode and the semiconductor substrate, between the second gate electrode and the semiconductor substrate, and on the front surface side of the neck portion, is provided.

Abstract: A first parallel pn layer having a first n-type region and a first p-type region junctioned alternately and repeatedly is disposed in an element active portion. The first parallel pn layer has a striped planar layout. A second parallel pn layer having a second n-type region and a second p-type region junctioned alternately and repeatedly is disposed in a high voltage structure. The second parallel pn layer has a striped planar layout in a direction identical to that of the first parallel pn layer. An intermediate region having a third parallel pn layer and a fourth parallel pn layer of a lower impurity quantity than the first parallel pn layer is disposed between the first and second parallel pn layers, and formed by diffusing impurity implanting regions becoming the first and the second parallel pn layers formed separated from each other to a region in which no impurity is ion-implanted.

Abstract: A first parallel pn layer in which first n-type regions and first p-type regions are disposed in a plan view layout of stripes in an element active portion. A second parallel pn layer has a plan view layout of stripes oriented in the same direction as that of the stripes of the first parallel pn layer in a breakdown voltage structure portion. Corner portions of the first parallel pn layer has a plan view shape where stepped regions formed by shortening the length of the first n-type and p-type regions in steps are disposed in a stepwise arrangement. The stepped regions continue with a second parallel pn layer via an intermediate region lower in average impurity concentration than the first parallel pn layer.