Abstract: A high-voltage MOS transistor has a semiconductor substrate formed with a first well of a first conductivity type in which a drain region and a drift region are formed and a second well of a second, opposite conductivity type in which a source region and a channel region are formed, a gate electrode extends over the substrate from the second well to the first well via a gate insulation film, wherein there is formed a buried insulation film in the drift region underneath the gate insulation film at a drain edge of the gate electrode, there being formed an offset region in the semiconductor substrate between the channel region and the buried insulation film, wherein the resistance of the offset region is reduced in a surface part thereof by being introduced with an impurity element of the first conductivity type with a concentration exceeding the first well.

Abstract: A semiconductor device including a silicon substrate including a first region and a second region; a gate electrode above the first region and the second region; an insulation film extending from the gate electrode to the second region to cover part of the gate electrode and part of the second region; a source region and a drain region formed in the silicon substrate, silicide formed on the source region, on the drain region, and on the gate electrode; an interlayer insulation film formed above the gate electrode and the insulation film; a first electrically conductive via formed in the interlayer insulation film, a second electrically conductive via formed in the interlayer insulation, and a third electrically conductive via formed in the interlayer insulation and electrically connecting to the gate electrode; and at least one electrically conductive member formed on the insulation film in the interlayer insulation film.

Abstract: A semiconductor device including a silicon substrate including a first region and a second region; a gate electrode above the first region and the second region; an insulation film extending from the gate electrode to the second region to cover part of the gate electrode and part of the second region; a source region and a drain region formed in the silicon substrate, silicide formed on the source region, on the drain region, and on the gate electrode; an interlayer insulation film formed above the gate electrode and the insulation film; a first electrically conductive via formed in the interlayer insulation film, a second electrically conductive via formed in the interlayer insulation, and a third electrically conductive via formed in the interlayer insulation and electrically connecting to the gate electrode; and at least one electrically conductive member formed on the insulation film in the interlayer insulation film.

Abstract: A disclosed MOS transistor has a drain region offset from a gate electrode structure, wherein the gate electrode structure includes at least a first gate electrode and a second gate electrode such that the second gate electrode is located at the drain side of the first gate electrode and the second gate electrode is isolated from the first gate electrode by an insulation film, and wherein the first and second gate electrodes are formed respectively on a first gate insulation film and a second gate insulation film having an increased thickness as compared with the first gate insulation film.

Abstract: A semiconductor device production method includes: forming in a silicon substrate first and second region of first and second conductivity type in contact with each other; forming a gate electrode above the first and the second region; forming an insulation film covering part of the gate electrode and part of the second region; forming a source region and a drain region of the second conductivity type; forming interlayer insulation film covering the gate electrode and the insulation film; and forming in the interlayer insulation film first, second and third contact hole reaching the source region, the drain region, and the gate electrode, respectively, and at least one additional hole reaching the insulation film, and forming a conductive film in the first, the second, and the third contact hole and the additional hole to form first, second and third electrically conductive via and electrically conductive member.

Abstract: A semiconductor device production method includes: forming in a silicon substrate first and second region of first and second conductivity type in contact with each other; forming a gate electrode above the first and the second region; forming an insulation film covering part of the gate electrode and part of the second region; forming a source region and a drain region of the second conductivity type; forming interlayer insulation film covering the gate electrode and the insulation film; and forming in the interlayer insulation film first, second and third contact hole reaching the source region, the drain region, and the gate electrode, respectively, and at least one additional hole reaching the insulation film, and forming a conductive film in the first, the second, and the third contact hole and the additional hole to form first, second and third electrically conductive via and electrically conductive member.

Abstract: A high-voltage MOS transistor has a semiconductor substrate formed with a first well of a first conductivity type in which a drain region and a drift region are formed and a second well of a second, opposite conductivity type in which a source region and a channel region are formed, a gate electrode extends over the substrate from the second well to the first well via a gate insulation film, wherein there is formed a buried insulation film in the drift region underneath the gate insulation film at a drain edge of the gate electrode, there being formed an offset region in the semiconductor substrate between the channel region and the buried insulation film, wherein the resistance of the offset region is reduced in a surface part thereof by being introduced with an impurity element of the first conductivity type with a concentration exceeding the first well.

Abstract: A disclosed MOS transistor has a drain region offset from a gate electrode structure, wherein the gate electrode structure includes at least a first gate electrode and a second gate electrode such that the second gate electrode is located at the drain side of the first gate electrode and the second gate electrode is isolated from the first gate electrode by an insulation film, and wherein the first and second gate electrodes are formed respectively on a first gate insulation film and a second gate insulation film having an increased thickness as compared with the first gate insulation film.

Abstract: A method of manufacturing a semiconductor device includes forming a gate insulating film over a semiconductor substrate, forming a silicon film over the gate insulating film, forming a resist pattern over the silicon film, etching the silicon film to form a protrusion portion of the silicon film, forming a dummy film over the silicon film, etching the dummy film so that the dummy film is partially remained on sidewalls of the protrusion portion, etching the silicon film using the remaining dummy film to form a gate electrode, and performing ion implantation into the semiconductor substrate to form source/drain regions.

Abstract: A method of manufacturing a semiconductor device includes forming a gate insulating film over a semiconductor substrate, forming a silicon film over the gate insulating film, forming a resist pattern over the silicon film, etching the silicon film to form a protrusion portion of the silicon film, forming a dummy film over the silicon film, etching the dummy film so that the dummy film is partially remained on sidewalls of the protrusion portion, etching the silicon film using the remaining dummy film to form a gate electrode, and performing ion implantation into the semiconductor substrate to form source/drain regions.

Abstract: A semiconductor device manufacturing method capable of making in-plane temperature distribution on a wafer uniform at heat treatment time. Before heat treatment is performed by irradiating the wafer with lamp light from the side of a device formed area where semiconductor devices are to be formed, an SiN film with certain thickness the reflection factor of which is equal to the average reflection factor of the device formed area is formed in an edge portion outside the device formed area. By doing so, reflection factors on the surface of the wafer irradiated with lamp light can be made uniform and uniform temperature distribution on the wafer can be obtained at heat treatment time. As a result, in-plane variations in the characteristics of semiconductor devices on the wafer can be made small and high-quality semiconductor devices can be manufactured.

Abstract: A semiconductor device manufacturing method capable of making in-plane temperature distribution on a wafer uniform at heat treatment time. Before heat treatment is performed by irradiating the wafer with lamp light from the side of a device formed area where semiconductor devices are to be formed, an SiN film with certain thickness the reflection factor of which is equal to the average reflection factor of the device formed area is formed in an edge portion outside the device formed area. By doing so, reflection factors on the surface of the wafer irradiated with lamp light can be made uniform and uniform temperature distribution on the wafer can be obtained at heat treatment time. As a result, in-plane variations in the characteristics of semiconductor devices on the wafer can be made small and high-quality semiconductor devices can be manufactured.

Abstract: When an isolation insulating film is formed, first, by thermal oxidation method, a silicon oxide film having a thickness of about 5 nm is formed. Next, a silicon nitride film having a thickness of about 3 nm to about 20 nm is formed. The silicon oxide film and the silicon nitride film serve as a liner film. When the silicon nitride film is formed, BTBAS is used as a growth gas, and NH3 gas is also supplied. As for conditions, the temperature of the substrate is set to be 600° C. or lower, the pressure inside the chamber is set to be 200 Pa or lower, and the flow rate of BTBAS and NH3 (NH3/BTBAS) is set to be 0.1 to 30. After forming the silicon nitride film, the silicon oxide film is formed by a high density plasma method. Then, it is flattened using a CMP method or the like.

Abstract: The present invention realizes a heterobipolar transistor using a SiGeC base layer in order to improve its electric characteristics. Specifically, the distribution of carbon and boron within the base layer is controlled so that the concentration of boron is higher than the concentration of carbon on the side bordering on the emitter layer, and upon the formation of the emitter layer, both boron and carbon are dispersed into a portion of the emitter layer that comes into contact with the base layer.

Abstract: A semiconductor device manufacturing method capable of making in-plane temperature distribution on a wafer uniform at heat treatment time. Before heat treatment is performed by irradiating the wafer with lamp light from the side of a device formed area where semiconductor devices are to be formed, an SiN film with certain thickness the reflection factor of which is equal to the average reflection factor of the device formed area is formed in an edge portion outside the device formed area. By doing so, reflection factors on the surface of the wafer irradiated with lamp light can be made uniform and uniform temperature distribution on the wafer can be obtained at heat treatment time. As a result, in-plane variations in the characteristics of semiconductor devices on the wafer can be made small and high-quality semiconductor devices can be manufactured.

Abstract: The present invention realizes a heterobipolar transistor using a SiGeC base layer in order to improve its electric characteristics. Specifically, the distribution of carbon and boron within the base layer is controlled so that the concentration of boron is higher than the concentration of carbon on the side bordering on the emitter layer, and upon the formation of the emitter layer, both boron and carbon are dispersed into a portion of the emitter layer that comes into contact with the base layer.

Abstract: The present invention realizes a heterobipolar transistor using a SiGeC base layer in order to improve its electric characteristics. Specifically, the distribution of carbon and boron within the base layer is controlled so that the concentration of boron is higher than the concentration of carbon on the side bordering on the emitter layer, and upon the formation of the emitter layer, both boron and carbon are dispersed into a portion of the emitter layer that comes into contact with the base layer.

Abstract: A semiconductor device manufacturing method capable of making in-plane temperature distribution on a wafer uniform at heat treatment time. Before heat treatment is performed by irradiating the wafer with lamp light from the side of a device formed area where semiconductor devices are to be formed, an SiN film with certain thickness the reflection factor of which is equal to the average reflection factor of the device formed area is formed in an edge portion outside the device formed area. By doing so, reflection factors on the surface of the wafer irradiated with lamp light can be made uniform and uniform temperature distribution on the wafer can be obtained at heat treatment time. As a result, in-plane variations in the characteristics of semiconductor devices on the wafer can be made small and high-quality semiconductor devices can be manufactured.

Abstract: When a silicon-germanium mixed crystal layer is grown on a substrate by introducing a silicon source gas, a germanium source gas, a boron source gas, and a carbon source gas into a reaction chamber, the flow rate of the carbon source gas is set at 5 sccm or higher and the supply concentration of the carbon source gas is set as low as approximately 1.0% under the condition that the silicon-germanium mixed crystal layer is doped with carbon with a concentration of approximately 0.5%; resulting in, carbon with a concentration required to inhibit the diffusion of boron is doped into the layer and the concentration of carbon becomes equal to or higher than the concentration of boron in a region at any given depth.

Abstract: The present invention realizes a heterobipolar transistor using a SiGeC base layer in order to improve its electric characteristics. Specifically, the distribution of carbon and boron within the base layer is controlled so that the concentration of boron is higher than the concentration of carbon on the side bordering on the emitter layer, and upon the formation of the emitter layer, both boron and carbon are dispersed into a portion of the emitter layer that comes into contact with the base layer.