Abstract: A p-channel MOS transistor includes first and second SiGe mixed crystal regions formed epitaxially to a silicon substrate at respective outer sides of sidewall insulation films of a gate electrode so as to fill respective trenches formed in source and drain diffusion regions of p-type respectively, wherein the p-channel MOS transistor further includes a compressive stressor film covering the silicon substrate and the sidewall insulation films continuously.

Abstract: A semiconductor device includes a gate electrode formed on a silicon substrate in correspondence to a channel region via a gate insulation film, and source and drain regions of p-type formed in the silicon substrate at respective outer sides of sidewall insulation films on the gate electrode, a pair of SiGe mixed crystal regions formed in the silicon substrate at respective outer sides of the sidewall insulation films epitaxially to the silicon substrate so as to be enclosed respectively by the source and drain regions, each of the SiGe mixed crystal regions being grown to a level above a level of a gate insulation film interface between the gate insulation film and the silicon substrate, wherein there is provided a compressive stress film at respective top surfaces of the SiGe mixed crystal regions.

Abstract: A semiconductor integrated circuit includes an n-channel MOS transistor and a p-channel MOS transistor formed respectively in first and second device regions of a substrate, the n-channel MOS transistor including a first gate electrode carrying sidewall insulation films on respective sidewall surfaces thereof, the p-channel MOS transistor including a second gate electrode carrying sidewall insulation films on respective sidewall surfaces thereof, wherein there is provided a stressor film on the substrate over the first and second device regions such that the stressor film covers the first gate electrode including the sidewall insulation films thereof and the second gate electrode including the sidewall insulation films thereof, wherein the stressor film has a decreased film thickness in the second device region at least in the vicinity of a base part of the second gate electrode.

Abstract: A p-channel MOS transistor includes a strained SOI substrate formed of a SiGe mixed crystal layer and a strained Si layer formed on the SiGe mixed crystal layer via an insulation film, a channel region being formed in the strained Si layer, a gate electrode formed on the strained Si layer in correspondence to the channel region via a gate insulation film, and first and second p-type diffusion regions formed in the strained Si layer at respective first and second sides of the channel region, wherein the strained Si layer has first and second sidewall surfaces respectively at the first and second sides thereof, a first SiGe mixed crystal region being formed epitaxially to the SiGe mixed crystal layer in contact with the first sidewall surface, a second SiGe mixed crystal region being formed epitaxially to the SiGe mixed crystal layer in contact with the second sidewall surface, the first and second SiGe mixed crystal regions being in lattice matching with the strained silicon layer respectively at the first and

Abstract: A semiconductor integrated circuit device includes an n-channel MOS transistor formed on a first device region of a silicon substrate and a p-channel MOS transistor formed on a second device region of the silicon substrate, wherein the n-channel MOS transistor includes a first gate electrode carrying a pair of first sidewall insulation films formed on respective sidewall surfaces thereof, the p-channel MOS transistor includes a second gate electrode carrying a pair of second sidewall insulation films formed on respective sidewall surfaces thereof, first and second SiGe mixed crystal regions being formed in the second device region epitaxially so as to fill first and second trenches formed at respective, outer sides of the second sidewall insulation films so as to be included in source and drain diffusions of the p-channel MOS transistor, a distance between n-type source and drain diffusion region in the first device region being larger than a distance between the p-type source and drain diffusion regions in t

Abstract: A high-speed, low-power-consumption semiconductor device has a thin-film Si layer with a source/drain formed therein. The thin-film Si layer is curved from a region directly below a gate electrode toward a region near the source/drain. The curved thin-film Si layer develops strains in a channel region disposed directly below the gate electrode sandwiched by the source/drain in the thin-film Si layer, for thereby increasing a carrier mobility. A cavity is defined below the curved thin-film Si layer for reducing a parasitic capacitance due to a pn junction.

Abstract: A semiconductor device includes a gate electrode formed on a silicon substrate via a gate insulation film in correspondence to a channel region, source and drain regions of a p-type diffusion region formed in the silicon substrate at respective outer sides of sidewall insulation films of the gate electrode, and a pair of SiGe mixed crystal regions formed in the silicon substrate at respective outer sides of the sidewall insulation films in epitaxial relationship to the silicon substrate, the SiGe mixed crystal regions being defined by respective sidewall surfaces facing with each other, wherein, in each of the SiGe mixed crystal regions, the sidewall surface is defined by a plurality of facets forming respective, mutually different angles with respect to a principal surface of the silicon substrate.

Abstract: A high-speed, low-power-consumption semiconductor device has a thin-film Si layer with a source/drain formed therein. The thin-film Si layer is curved from a region directly below a gate electrode toward a region near the source/drain. The curved thin-film Si layer develops strains in a channel region disposed directly below the gate electrode sandwiched by the source/drain in the thin-film Si layer, for thereby increasing a carrier mobility. A cavity is defined below the curved thin-film Si layer for reducing a parasitic capacitance due to a pn junction.

Abstract: A high-speed, low-power-consumption semiconductor device has a thin-film Si layer with a source/drain formed therein. The thin-film Si layer is curved from a region directly below a gate electrode toward a region near the source/drain. The curved thin-film Si layer develops strains in a channel region disposed directly below the gate electrode sandwiched by the source/drain in the thin-film Si layer, for thereby increasing a carrier mobility. A cavity is defined below the curved thin-film Si layer for reducing a parasitic capacitance due to a pn junction.

Abstract: A metal-semiconductor junction comprising a wiring metal layer and a semiconductor layer. To reduce the contact resistance of the junction, a region doped with an n- or p-type impurity and having a high carrier concentration of 1021 cm−3 or more is provided in a near-surface part of the semiconductor layer (at a distance of 10 nm or less from the metal layer. The high-carrier concentration region is composed of n- or p-type impurity layers and IV-group semiconductor layers that have been alternately deposited upon another by means of, for example, vapor-phase growth.

Abstract: A metal-semiconductor junction comprising a wiring metal layer and a semiconductor layer. To reduce the contact resistance of the junction, a region doped with an n- or p-type impurity and having a high carrier concentration of 1021 cm−3 or more is provided in a near-surface part of the semiconductor layer (at a distance of 10 nm or less from the metal layer. The high-carrier concentration region is composed of n -or p-type impurity layers and IV-group semiconductor layers that have been alternately deposited upon another by means of, for example, vapor-phase growth.

Abstract: A metal-semiconductor junction comprises a wiring metal layer and a semiconductor layer. To reduce the contact resistance of the junction, a region doped with an n- or p-type impurity and having a high carrier concentration of 1021 cm−3 or more is provided in a near-surface part of the semiconductor layer (at a distance of 10 nm or less from the metal layer. The high-carrier concentration region is composed of n- or p-type impurity layers and IV-group semiconductor layers that have been alternately deposited upon another by means of, for example, vapor-phase growth.

Abstract: A metal-semiconductor junction comprising a wiring metal layer and a semiconductor layer. To reduce the contact resistance of the junction, a region doped with an n- or p-type impurity and having a high carrier concentration of 1021 cm−3 or more is provided in a near-surface part of the semiconductor layer (at a distance of 10 nm or less from the metal layer. The high-carrier concentration region is composed of n- or p-type impurity layers and IV-group semiconductor layers that have been alternately deposited upon another by means of, for example, vapor-phase growth.