Abstract: A method of manufacturing a semiconductor device includes: forming a silicon oxide film covering each of a first main surface and a second main surface of a semiconductor substrate; forming a redistribution wiring on the first main surface side of the semiconductor substrate; and grinding the second main surface of the semiconductor substrate. This grinding step is performed in a state in which a thickness of the silicon oxide film positioned on the second main surface is equal to or larger than 10 nm and equal to or smaller than 30 nm.

Abstract: In a memory cell forming region including a dummy cell region, a plurality of fins which are parts of a semiconductor substrate, protrude from an upper surface of an element isolation portion and are formed adjacent to each other. A distance between a fin closest to a dummy fin among the plurality of fins and the dummy fin is shorter than a distance between two fins adjacent to each other. As a result, a position of an upper surface of the element isolation portion formed between two fins adjacent to each other and a position of an upper surface of the element isolation portion STI formed between the fin closest to the dummy fin and the dummy fin is lower than a position of an upper surface of the element isolation portion STI formed in a shunt region.

Abstract: In a memory cell forming region including a dummy cell region, a plurality of fins which are parts of a semiconductor substrate, protrude from an upper surface of an element isolation portion and are formed adjacent to each other, are formed. A distance between a fin closest to a dummy fin among the plurality of fins and the dummy fin is shorter than a distance between two fins adjacent to each other. As a result, a position of an upper surface of the element isolation portion formed between two fins adjacent to each other and a position of an upper surface of the element isolation portion STI formed between the fin closest to the dummy fin and the dummy fin is lower than a position of an upper surface of the element isolation portion STI formed in a shunt region.

Abstract: In manufacturing a trench type MOSFET, reliability of a semiconductor device is prevented from being degraded due to a short circuit or lowering of withstand voltage between a trench gate electrode and a source region. To achieve the above, poly-silicon films are formed inside a trench in a main surface of a semiconductor substrate and over the semiconductor substrate. Further, phosphorus is thermally diffused into each poly-silicon film from a phosphorous film over an upper surface of the poly-silicon film. Still further, a silicon oxide film formed in a surface layer of the poly-silicon film by the thermal diffusion process is removed by a first dry etching process using a fluorocarbon gas or a hydroxy-fluorocarbon gas. Then, by performing a second dry etching process using a Cl2 gas etc., an insulating film is exposed and, thereby, a trench gate electrode including the poly-silicon film is formed.

Abstract: A semiconductor device with enhanced reliability in which a gate electrode for a trench-gate field effect transistor is formed through a gate insulating film in a trench made in a semiconductor substrate. The upper surface of the gate electrode is in a lower position than the upper surface of the semiconductor substrate in an area adjacent to the trench. A sidewall insulating film is formed over the gate electrode and over the sidewall of the trench. The gate electrode and the sidewall insulating film are covered by an insulating film as an interlayer insulating film.

Abstract: A semiconductor device with enhanced reliability in which a gate electrode for a trench-gate field effect transistor is formed through a gate insulating film in a trench made in a semiconductor substrate. The upper surface of the gate electrode is in a lower position than the upper surface of the semiconductor substrate in an area adjacent to the trench. A sidewall insulating film is formed over the gate electrode and over the sidewall of the trench. The gate electrode and the sidewall insulating film are covered by an insulating film as an interlayer insulating film.

Abstract: In manufacturing a trench type MOSFET, reliability of a semiconductor device is prevented from being degraded due to a short circuit or lowering of withstand voltage between a trench gate electrode and a source region. To achieve the above, poly-silicon films are formed inside a trench in a main surface of a semiconductor substrate and over the semiconductor substrate. Further, phosphorus is thermally diffused into each poly-silicon film from a phosphorous film over an upper surface of the poly-silicon film. Still further, a silicon oxide film formed in a surface layer of the poly-silicon film by the thermal diffusion process is removed by a first dry etching process using a fluorocarbon gas or a hydroxy-fluorocarbon gas. Then, by performing a second dry etching process using a Cl2 gas etc., an insulating film is exposed and, thereby, a trench gate electrode including the poly-silicon film is formed.

Abstract: A semiconductor device with enhanced reliability in which a gate electrode for a trench-gate field effect transistor is formed through a gate insulating film in a trench made in a semiconductor substrate. The upper surface of the gate electrode is in a lower position than the upper surface of the semiconductor substrate in an area adjacent to the trench. A sidewall insulating film is formed over the gate electrode and over the sidewall of the trench. The gate electrode and the sidewall insulating film are covered by an insulating film as an interlayer insulating film.

Abstract: A semiconductor device with enhanced reliability in which a gate electrode for a trench-gate field effect transistor is formed through a gate insulating film in a trench made in a semiconductor substrate. The upper surface of the gate electrode is in a lower position than the upper surface of the semiconductor substrate in an area adjacent to the trench. A sidewall insulating film is formed over the gate electrode and over the sidewall of the trench. The gate electrode and the sidewall insulating film are covered by an insulating film as an interlayer insulating film.

Abstract: A semiconductor device with enhanced reliability in which a gate electrode for a trench-gate field effect transistor is formed through a gate insulating film in a trench made in a semiconductor substrate. The upper surface of the gate electrode is in a lower position than the upper surface of the semiconductor substrate in an area adjacent to the trench. A sidewall insulating film is formed over the gate electrode and over the sidewall of the trench. The gate electrode and the sidewall insulating film are covered by an insulating film as an interlayer insulating film.

Abstract: A brushless motor has a first coupler that includes a molded body with an annular member and a plug integrally combined with a peripheral side wall of the annular member. The plug houses terminal rods therein. Bridges project radially inward from an inner peripheral wall surface of the annular member. Connectors joined to respective leads that extend from an electromagnetic coil are mounted on radial inner ends of the bridges. The bridges axe provided in pairs of adjacent bridges. In each of such pairs, the bridges project in parallel with each other from an inner peripheral wall surface of the annular member.

Abstract: A method of manufacture of a semiconductor device includes forming a gate insulating film and gate electrode made of polycrystalline silicon over a semiconductor substrate; implanting ions into the semiconductor substrate to form a semiconductor region as a source or drain; forming a cobalt film and a titanium nitride film over the semiconductor substrate to cover the gate electrode; carrying out annealing to cause a reaction between Co and Si and the semiconductor region to form a CoSi layer; carrying out wet cleaning to remove the titanium nitride film and unreacted cobalt film to leave the CoSi layer over the gate electrode and semiconductor region; carrying out annealing to cause a reaction between the CoSi layer and the gate electrode and semiconductor region to form a CoSi2 layer; carrying out HPM cleaning; and forming over the semiconductor substrate a silicon nitride film by low-pressure CVD to cover the gate electrode.

Abstract: A brushless motor has a first coupler comprising a molded body including an annular member and a plug integrally combined with a peripheral side wall of the annular member. The plug houses terminal rods therein. Bridges project radially inward from an inner peripheral wall surface of the annular member. Connectors joined to respective leads that extend from an electromagnetic coil are mounted on radial inner ends of the bridges. The bridges are provided in pairs of adjacent bridges. In each of such pairs, the bridges project in parallel with each other from an inner peripheral wall surface of the annular member.

Abstract: A method of manufacture of a semiconductor device includes forming a gate insulating film and gate electrode made of polycrystalline silicon over a semiconductor substrate; implanting ions into the semiconductor substrate to form a semiconductor region as a source or drain; forming a cobalt film and a titanium nitride film over the semiconductor substrate to cover the gate electrode; carrying out annealing to cause a reaction between Co and Si and the semiconductor region to form a CoSi layer; carrying out wet cleaning to remove the titanium nitride film and unreacted cobalt film to leave the CoSi layer over the gate electrode and semiconductor region; carrying out annealing to cause a reaction between the CoSi layer and the gate electrode and semiconductor region to form a CoSi2 layer; carrying out HPM cleaning; and forming over the semiconductor substrate a silicon nitride film by low-pressure CVD to cover the gate electrode.

Abstract: A method of manufacture of a semiconductor device includes forming a gate insulating film and a gate electrode made of polycrystalline silicon over a semiconductor substrate; implanting ions into the semiconductor substrate to form a semiconductor region as a source or drain; forming a cobalt film and a titanium nitride film over the semiconductor substrate to cover the gate electrode; carrying out annealing to cause a reaction between Co and Si and the semiconductor region to form a CoSi layer; carrying out wet cleaning to remove the titanium nitride film and unreacted cobalt film to leave the CoSi layer over the gate electrode and semiconductor region; carrying out annealing to cause a reaction between the CoSi layer and the gate electrode and semiconductor region to form a CoSi2 layer; carrying out HPM cleaning; and forming over the semiconductor substrate a silicon nitride film by low-pressure CVD to cover the gate electrode.

Abstract: In a high-performance semiconductor integrated circuit, the standby current is reduced by preventing current leakage in a semiconductor integrated circuit device, for example, the memory cell of an SRAM. A gate electrode G is formed on semiconductor substrate 1 and n+-type semiconductor regions 17 (source/drain regions) are formed in the semiconductor substrate on both sides of this gate electrode. Within the same apparatus and under near-vacuum conditions, a depth of 2.5 nm or less is etched away from the surfaces of the source/drain regions and gate electrode, a film of Co is then formed on the source/drain regions, and thermal processing is applied to form CoSi2 layer 19a. As a result, current leakage in the memory cell can be prevented and this method can be applied to semiconductor integrated circuit devices that have low current consumption or are battery-driven.

Abstract: A method of manufacture of a semiconductor device includes forming a gate insulating film and a gate electrode made of polycrystalline silicon over a semiconductor substrate; implanting ions into the semiconductor substrate to form a semiconductor region as a source or drain; forming a cobalt film and a titanium nitride film over the semiconductor substrate to cover the gate electrode; carrying out annealing to cause a reaction between Co and Si and the semiconductor region to form a CoSi layer; carrying out wet cleaning to remove the titanium nitride film and unreacted cobalt film to leave the CoSi layer over the gate electrode and semiconductor region; carrying out annealing to cause a reaction between the CoSi layer and the gate electrode and semiconductor region to form a CoSi2 layer; carrying out HPM cleaning; and forming over the semiconductor substrate a silicon nitride film by low-pressure CVD to cover the gate electrode.

Abstract: To provide a high-performance semiconductor integrated circuit in which the standby current is reduced by preventing current leakage in a semiconductor integrated circuit device, for example, the memory cell of an SRAM.