Abstract: A single crystal semiconductor layer of a first conduction type is disposed on a surface of a semiconductor substrate. A plurality of trenches are provided in the semiconductor layer to form a plurality of first semiconductor regions of the first conduction type at intervals in a direction parallel to the surface. An epitaxial layer is buried in the plurality of trenches to form a plurality of second semiconductor regions of a second conduction type. The plurality of second semiconductor regions each includes an outer portion with a high impurity concentration formed against an inner wall of the trench, and an inner portion with a low impurity concentration formed inner than the outer portion.

Abstract: A cathode potential is applied to a conductive layer formed on a substrate having a depression pattern. A plating solution in electrical contact with an anode is supplied to the conductive layer to form a plating film on the conductive layer. At this time, the plating solution is supplied by causing an impregnated member containing the plating solution to face the conductive layer. Since the plating solution stays in the depression, a larger amount of plating solution is supplied than on the upper surface of the substrate, and the plating rate of the plating film in the depression increases. Consequently, the plating film can be preferentially formed in the depression such as a groove or hole.

Abstract: In a remote access server (RAS), the number of logical link resources, which are circuit resources between the RAS and an ISP server, is set greater than the number of physical link resources, which are circuit resources between the RAS and each terminal device. In the RAS, when a particular circuit undergoes a transition to the dormant state, only the physical link resource is released to allow use by other terminal devices while the logical link resource is maintained unchanged in a connected state, whereby the loss probability is reduced without increasing the number of physical link resources.

Abstract: A plating method and apparatus for a substrate fills a metal, e.g., copper, into a fine interconnection pattern formed in a semiconductor substrate. The apparatus has a substrate holding portion 36 horizontally holding and rotating a substrate with its surface to be plated facing upward. A seal material 90 contacts a peripheral edge portion of the surface, sealing the portion in a watertight manner. A cathode electrode 88 passes an electric current upon contact with the substrate. A cathode portion 38 rotates integrally with the substrate holding portion 36. An electrode arm portion 30 is above the cathode portion 38 and movable horizontally and vertically and has an anode 98 face-down. Plating liquid is poured into a space between the surface to be plated and the anode 98 brought close to the surface to be plated. Thus, plating treatment and treatments incidental thereto can be performed by a single unit.

Abstract: A plating method and apparatus for a substrate fills a metal, e.g., copper, into a fine interconnection pattern formed in a semiconductor substrate. The apparatus has a substrate holding portion 36 horizontally holding and rotating a substrate with its surface to be plated facing upward. A seal material 90 contacts a peripheral edge portion of the surface, sealing the portion in a watertight manner. A cathode electrode 88 passes an electric current upon contact with the substrate. A cathode portion 38 rotates integrally with the substrate holding portion 36. An electrode arm portion 30 is above the cathode portion 38 and movable horizontally and vertically and has an anode 98 face-down. Plating liquid is poured into a space between the surface to be plated and the anode 98 brought close to the surface to be plated. Thus, plating treatment and treatments incidental thereto can be performed by a single unit.

Abstract: A first semiconductor pillar layer of a first conductivity type is formed on a main surface of a semiconductor substrate of the first conductivity type. A second semiconductor pillar layer of a second conductivity type is formed adjacent to the first semiconductor pillar layer. A third semiconductor pillar layer of the first conductivity type is formed adjacent to the second semiconductor pillar layer. A semiconductor base layer of the second conductivity type is formed on the main surface of the second semiconductor pillar layer. An insulated-gate type semiconductor element is formed in the semiconductor base layer. The carrier concentration on the side of a main surface of each of said first through third semiconductor pillar layers is higher than a carrier concentration on the opposite side of said main surface in each of said first through third semiconductor pillar layers.

Abstract: A plating method and apparatus for a substrate fills a metal, e.g., copper, into a fine interconnection pattern formed in a semiconductor substrate. The apparatus has a substrate holding portion 36 horizontally holding and rotating a substrate with its surface to be plated facing upward. A seal material 90 contacts a peripheral edge portion of the surface, sealing the portion in a watertight manner. A cathode electrode 88 passes an electric current upon contact with the substrate. A cathode portion 38 rotates integrally with the substrate holding portion 36. An electrode arm portion 30 is above the cathode portion 38 and movable horizontally and vertically and has an anode 98 face-down. Plating liquid is poured into a space between the surface to be plated and the anode 98 brought close to the surface to be plated. Thus, plating treatment and treatments incidental thereto can be performed by a single unit.

Abstract: Disclosed is a method of manufacturing an electronic device, comprising forming a concave portion on the surface of a base member, forming an electrically conductive seed layer on that surface of the base member on which a plated film is to be formed, and applying an electrolytic plating treatment with the seed layer used as a common electrode under the condition that a substance for accelerating the electrolytic plating is allowed to be present in the concave portion of the base member in an amount larger than that on the surface of the base member to form a plated film.

Abstract: A single crystal semiconductor layer of a first conduction type is disposed on a surface of a semiconductor substrate. A plurality of trenches are provided in the semiconductor layer to form a plurality of first semiconductor regions of the first conduction type at intervals in a direction parallel to the surface. An epitaxial layer is buried in the plurality of trenches to form a plurality of second semiconductor regions of a second conduction type. The plurality of second semiconductor regions each includes an outer portion with a high impurity concentration formed against an inner wall of the trench, and an inner portion with a low impurity concentration formed inner than the outer portion.

Abstract: A first semiconductor pillar layer of a first conductivity type is formed on a main surface of a semiconductor substrate of the first conductivity type. A second semiconductor pillar layer of a second conductivity type is formed adjacent to the first semiconductor pillar layer. A third semiconductor pillar layer of the first conductivity type is formed adjacent to the second semiconductor pillar layer. A semiconductor base layer of the second conductivity type is formed on the main surface of the second semiconductor pillar layer. An insulated-gate type semiconductor element is formed in the semiconductor base layer. The carrier concentration on the side of a main surface of each of said first through third semiconductor pillar layers is higher than a carrier concentration on the opposite side of said main surface in each of said first through third semiconductor pillar layers.

Abstract: A semiconductor device comprises a semiconductor layer which includes a terminate end part and a cell formation part that is surrounded by this end part, and a plurality of guard rings each of which is formed at the end part to surround the cell formation part. These guard rings are made shallower and smaller in width as they get near to the guard ring that resides at the outside position.

Abstract: An electronic device manufacturing method comprises forming an insulating film above a substrate, forming a to-be-filled region which includes at least one of an interconnection groove and a hole in the insulating film, forming a first conductive film containing a catalyst metal which accelerates electroless plating, so as to line an internal surface of the to-be-filled region, forming a second conductive film on the first conductive film by the electroless plating, so as to line the internal surface of the to-be-filled region via the first conductive film, and forming a third conductive film on the second conductive film by electroplating, so as to fill the to-be-filled region via the first conductive film and the second conductive film.

Abstract: A semiconductor device comprises a semiconductor substrate. A plurality of first semiconductor regions are formed in a single crystal semiconductor layer of a first conduction type disposed on a surface of the semiconductor substrate as defined by a plurality of trenches provided in the single crystal semiconductor layer. A plurality of insulating regions are respectively formed on bottoms in the trenches. A plurality of second semiconductor regions are formed of a single crystal semiconductor layer of a second conduction type buried in the trenches in the presence of the insulating regions formed therein. The first semiconductor regions and second semiconductor regions are arranged alternately in a direction parallel to the surface of the semiconductor substrate.

Abstract: A cathode potential is applied to a conductive layer formed on a substrate having a depression pattern. A plating solution in electrical contact with an anode is supplied to the conductive layer to form a plating film on the conductive layer. At this time, the plating solution is supplied by causing an impregnated member containing the plating solution to face the conductive layer. Since the plating solution stays in the depression, a larger amount of plating solution is supplied than on the upper surface of the substrate, and the plating rate of the plating film in the depression increases. Consequently, the plating film can be preferentially formed in the depression such as a groove or hole.

Abstract: An apparatus and a method for processing substrate are generally used for apparatuses for wet-type process of substrate, such as an electrolytic processing apparatus for use in forming interconnects by embedding a metal such as copper (Cu) or the like in fine interconnect patterns (recesses) that are formed in a substrate such as a semiconductor wafer and for use in forming bumps for electrical connections.

Abstract: A cathode potential is applied to a conductive layer formed on a substrate having a depression pattern. A plating solution in electrical contact with an anode is supplied to the conductive layer to form a plating film on the conductive layer. At this time, the plating solution is supplied by causing an impregnated member containing the plating solution to face the conductive layer. Since the plating solution stays in the depression, a larger amount of plating solution is supplied than on the upper surface of the substrate, and the plating rate of the plating film in the depression increases. Consequently, the plating film can be preferentially formed in the depression such as a groove or hole.

Abstract: A method of forming a cap film comprises a first polishing step of performing a polishing operation at selectivity of R1 (=removal rate for the cap film/removal rate for the insulating film), and a second polishing step of performing a polishing operation at selectivity of R2 (=removal rate for the cap film/removal rate for the insulating film). Each of the polishing operations is performed by using a slurry having the condition of R1>R2. By performing the polishing operations at different selectivity, the cap film free from problems such as dishing of the cap film and the residual cap film on side walls of a recess is formed. Consequently, a semiconductor device having an excellent RC characteristic can be provided.

Abstract: A method of manufacturing a semiconductor device comprising the steps of forming a dummy film and a dummy gate pattern at a predetermined gate-forming region on a semiconductor substrate, forming a first side wall insulating film on a side wall of the dummy gate pattern, forming an interlayer insulating film on a portion of the semiconductor substrate around the dummy gate pattern bearing the first side wall insulating film, forming a groove by removing the dummy gate pattern, removing a portion of dummy film exposed through the groove while leaving a portion of the first side wall insulating film as well as a portion of the dummy film disposed below the portion of the first side wall insulating film, forming a gate insulating film at least on a bottom surface of the groove, and forming a gate electrode on the gate insulating film formed in the groove.

Abstract: Disclosed is a method of manufacturing an electronic device, comprising forming a concave portion on the surface of a base member, forming an electrically conductive seed layer on that surface of the base member on which a plated film is to be formed, and applying an electrolytic plating treatment with the seed layer used as a common electrode under the condition that a substance for accelerating the electrolytic plating is allowed to be present in the concave portion of the base member in an amount larger than that on the surface of the base member to form a plated film.

Abstract: An electronic device manufacturing method comprises forming an insulating film above a substrate, forming a to-be-filled region which includes at least one of an interconnection groove and a hole in the insulating film, forming a first conductive film containing a catalyst metal which accelerates electroless plating, so as to line an internal surface of the to-be-filled region, forming a second conductive film on the first conductive film by the electroless plating, so as to line the internal surface of the to-be-filled region via the first conductive film, and forming a third conductive film on the second conductive film by electroplating, so as to fill the to-be-filled region via the first conductive film and the second conductive film.