Abstract: A field effect transistor according to one embodiment of the present invention is a field effect transistor which is supposed to be operated under a temperature condition at 300 K or less, comprising: an n-channel field effect transistor having a gate electrode formed by a gate electrode material having a work function WFn of less than 4.05. A field effect transistor according to one embodiment of the present invention is a field effect transistor which is supposed to be operated under a temperature condition at 300 K or less, comprising: a p-channel field effect transistor having a gate electrode formed by a gate electrode material having a work function WFp of more than 5.17.

Abstract: A semiconductor device according to an embodiment of the present invention comprises a first transistor including: a first source layer and a first drain layer both formed in one surface of a semiconductor substrate; a first silicide layer formed on the first source layer and the first drain layer; a first gate electrode formed on a first gate insulating film formed on the surface of the semiconductor substrate and having a second silicide layer; and a silicon nitride film formed on the sidewall of the first gate electrode; a second transistor including: a second source layer and a second drain layer both formed in the surface of the semiconductor substrate; a third silicide layer formed on the second source layer and the second drain layer and equal in thickness to the first silicide layer; a second gate electrode formed on a second gate insulating film formed on the surface of the semiconductor substrate and having a fourth silicide layer thinner in thickness than the second silicide layer.

Abstract: Provided is a semiconductor device, comprising a gate electrode formed on a semiconductor substrate, source/drain diffusion layers formed on both sides of the gate electrode, a gate electrode side-wall on the side of the source/drain diffusion layer and a gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode and having an L-shaped/reversed L-shaped cross-sectional shape, and a semiconductor layer extending over the gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode.

Abstract: A gate insulation film is formed on a semiconductor substrate. A gate electrode is formed on the gate insulation film. A silicide film is formed on the gate electrode. First gate sidewall films are formed on side surfaces of the gate electrode. Second gate sidewall films are formed on the first gate sidewall films on the side surfaces of the gate electrode. First sidewall films are formed on side surfaces of the silicide film on the gate electrode. A source region and a drain region are formed on the semiconductor substrate so as to sandwich a channel region formed under the gate insulation film. Second sidewall films are formed on end portions of the first and second gate sidewall films formed on the source region and the drain region.

Abstract: A gate electrode is provided via a gate insulating film formed between the source and drain regions on a semiconductor substrate, wherein the sidewall of the gate electrode excluding the exposed part formed at the upper part thereof facing the source and drain regions is covered with a sidewall insulating film, and an epitaxial film is formed on the exposed part of the sidewall of the gate electrode but not formed on a top surface of the gate electrode. An element isolation region formed on the semiconductor substrate is composed of a first insulating film formed in the semiconductor substrate and a second insulating film which is formed inside the first insulating film and has a lower epitaxial growth rate than that of the first insulating film, and the surface of the source and drain regions is covered with a silicon layer, part of which runs onto the surface of the first insulating film.

Abstract: Provided is a semiconductor device, comprising a gate electrode formed on a semiconductor substrate, source/drain diffusion layers formed on both sides of the gate electrode, a gate electrode side-wall on the side of the source/drain diffusion layer and a gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode and having an L-shaped/reversed L-shaped cross-sectional shape, and a semiconductor layer extending over the gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode.

Abstract: A semiconductor device having active regions connected by an interconnect line, which includes first and second transistors each having active regions and formed spaced apart from each other in a semiconductor substrate, an isolation region for isolating the first and second transistors from each other, a slit formed in the isolation region to allow those paired active regions of the first and second transistors which are opposed to each other with the isolation region interposed therebetween to communicate with each other through it, a conductive film formed on the inner walls of the slit, and an interconnect layer having first and second portions, each of which is electrically connected with a corresponding one of the paired active regions, and a third portion which is formed along the slit on the isolation region to connect the first and second portions with each other.

Abstract: Provided is a semiconductor device, comprising a gate electrode formed on a semiconductor substrate, source/drain diffusion layers formed on both sides of the gate electrode, a gate electrode side-wall on the side of the source/drain diffusion layer and a gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode and having an L-shaped/reversed L-shaped cross-sectional shape, and a semiconductor layer extending over the gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode.

Abstract: An aspect of the present invention includes a first MOSFET having a first gate electrode formed on a first semiconductor layer in a first region of a semiconductor substrate, a first channel region formed immediately below the first gate electrode in the first semiconductor layer, a first diffusion layer constituting source/drain regions formed at both the sides of the first channel region in the first semiconductor layer, a first epitaxial layer formed on the first diffusion layer, and a first silicide layer formed on the first epitaxial layer, and a second MOSFET having a second gate electrode formed on a second semiconductor layer in a second region of the semiconductor substrate, a second channel region formed immediately below the second gate electrode in the second semiconductor layer, a second diffusion layer constituting source/drain regions formed at both the sides of the second channel region in the second semiconductor layer, and a second silicide layer formed on the second diffusion layer.

Abstract: A semiconductor layer in which a primary part of a FinFET is formed, i.e., a fin has a shape which is long in a direction x and short in a direction y. A width of the fin in the direction y changes on three stages. First, in a channel area between gate electrodes each having a gate length Lg, the width of the fin in the direction y is Wch. Further, the width of the fin in the direction y in a source/drain extension area adjacent to the channel area in the direction x is Wext (>Wch). Furthermore, the width of the fin in the direction y in a source/drain area adjacent to the source/drain extension area in the direction x is Wsd (>Wext).

Abstract: A semiconductor device having active regions connected by an interconnect line, which includes first and second transistors each having active regions and formed spaced apart from each other in a semiconductor substrate, an isolation region for isolating the first and second transistors from each other, a slit formed in the isolation region to allow those paired active regions of the first and second transistors which are opposed to each other with the isolation region interposed therebetween to communicate with each other through it, a conductive film formed on the inner walls of the slit, and an interconnect layer having first and second portions, each of which is electrically connected with a corresponding one of the paired active regions, and a third portion which is formed along the slit on the isolation region to connect the first and second portions with each other.

Abstract: A semiconductor device has a first and a second semiconductor layer provided on an insulating film on a support substrate. A first memory cell transistor, which constitutes a part of a memory cell in an SRAM, has a first gate electrode of a first conductivity type and first source/drain diffusion layers of a second conductivity type opposite to the first conductivity type. The following expression is fulfilled the thickness of the first conductivity type≦one-third of a length of the first gate electrode in its channel length. A first peripheral transistor, which constitutes a part of a peripheral circuit, has a third gate electrode and a third source/drain diffusion layers. The following expression is satisfied the thickness of the second semiconductor layer>one-third of a length of the third gate electrode in its channel length direction.

Abstract: Provided is a semiconductor device, comprising a gate electrode formed on a semiconductor substrate, source/drain diffusion layers formed on both sides of the gate electrode, a gate electrode side-wall on the side of the source/drain diffusion layer and a gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode and having an L-shaped/reversed L-shaped cross-sectional shape, and a semiconductor layer extending over the gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode.

Abstract: A semiconductor device includes a p-type well region, n+-type diffusion regions formed in the surface region of the p-type well region, a gate electrode containing silicon and formed above the p-type well region with a gate insulating film disposed therebetween, and NiSi films formed in the surface regions of the n+-type diffusion regions. In the semiconductor device, p-type impurity is doped in the depth direction from the surface of the NiSi film and the impurity profile of p-type impurity is so formed that a peak concentration of not lower than 1E20 cm−3 will be provided in a preset depth position of the NiSi film and the concentration in the interface between the NiSi film and the n+-type diffusion region and the concentration in a position deeper than the interface will not be higher than 5E19 cm−3.

Abstract: An aspect of the present invention includes a first MOSFET having a first gate electrode formed on a first semiconductor layer in a first region of a semiconductor substrate, a first channel region formed immediately below the first gate electrode in the first semiconductor layer, a first diffusion layer constituting source/drain regions formed at both the sides of the first channel region in the first semiconductor layer, a first epitaxial layer formed on the first diffusion layer, and a first silicide layer formed on the first epitaxial layer, and a second MOSFET having a second gate electrode formed on a second semiconductor layer in a second region of the semiconductor substrate, a second channel region formed immediately below the second gate electrode in the second semiconductor layer, a second diffusion layer constituting source/drain regions formed at both the sides of the second channel region in the second semiconductor layer, and a second silicide layer formed on the second diffusion layer.

Abstract: Provided is a semiconductor device, comprising a gate electrode formed on a semiconductor substrate, source/drain diffusion layers formed on both sides of the gate electrode, a gate electrode side-wall on the side of the source/drain diffusion layer and a gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode and having an L-shaped/reversed L-shaped cross-sectional shape, and a semiconductor layer extending over the gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode.

Abstract: An aspect of the present invention includes a first MOSFET having a first gate electrode formed on a first semiconductor layer in a first region of a semiconductor substrate, a first channel region formed immediately below the first gate electrode in the first semiconductor layer, a first diffusion layer constituting source/drain regions formed at both the sides of the first channel region in the first semiconductor layer, a first epitaxial layer formed on the first diffusion layer, and a first silicide layer formed on the first epitaxial layer, and a second MOSFET having a second gate electrode formed on a second semiconductor layer in a second region of the semiconductor substrate, a second channel region formed immediately below the second gate electrode in the second semiconductor layer, a second diffusion layer constituting source/drain regions formed at both the sides of the second channel region in the second semiconductor layer, and a second silicide layer formed on the second diffusion layer.

Abstract: A gate electrode is provided via a gate insulating film formed between the source and drain regions on a semiconductor substrate, wherein the sidewall of the gate electrode excluding the exposed part formed at the upper part thereof facing the source and drain regions is covered with a sidewall insulating film, and an epitaxial film is formed on the exposed part of the sidewall of the gate electrode but not formed on a top surface of the gate electrode. An element isolation region formed on the semiconductor substrate is composed of a first insulating film formed in the semiconductor substrate and a second insulating film which is formed inside the first insulating film and has a lower epitaxial growth rate than that of the first insulating film, and the surface of the source and drain regions is covered with a silicon layer, part of which runs onto the surface of the first insulating film.

Abstract: A semiconductor device having active regions connected by an interconnect line, which includes first and second transistors each having active regions and formed spaced apart from each other in a semiconductor substrate, an isolation region for isolating the first and second transistors from each other, a slit formed in the isolation region to allow those paired active regions of the first and second transistors which are opposed to each other with the isolation region interposed therebetween to communicate with each other through it, a conductive film formed on the inner walls of the slit, and an interconnect layer having first and second portions, each of which is electrically connected with a corresponding one of the paired active regions, and a third portion which is formed along the slit on the isolation region to connect the first and second portions with each other.

Abstract: An aspect of the present invention includes a first MOSFET having a first gate electrode formed on a first semiconductor layer in a first region of a semiconductor substrate, a first channel region formed immediately below the first gate electrode in the first semiconductor layer, a first diffusion layer constituting source/drain regions formed at both the sides of the first channel region in the first semiconductor layer, a first epitaxial layer formed on the first diffusion layer, and a first silicide layer formed on the first epitaxial layer, and a second MOSFET having a second gate electrode formed on a second semiconductor layer in a second region of the semiconductor substrate, a second channel region formed immediately below the second gate electrode in the second semiconductor layer, a second diffusion layer constituting source/drain regions formed at both the sides of the second channel region in the second semiconductor layer, and a second silicide layer formed on the second diffusion layer.