Abstract: A semiconductor device comprises: a semiconductor substrate; an insulating layer provided on said semiconductor substrate; a first semiconductor layer provided on said insulating layer; a plurality of openings penetrating said first semiconductor layer and said insulating layer and reaching said semiconductor substrate; and second semiconductor layers filling said openings by selective growth and connected to said semiconductor substrate, wherein areal sizes of said plurality of openings are substantially equal to each other.

Abstract: A multi-input logic circuit (e.g. a 2-input NAND circuit) mounted on a semiconductor integrated circuit comprises a plurality of voltage-activated transistors which have the same channel conduction type and are electrically connected in series between a power supply terminal and an output terminal. A source region and a body region of at least the voltage-activated transistor connected to the output terminal are electrically connected and have substantially the same potential. The semiconductor integrated circuit has either an SOI or SOS structure.

Abstract: According to one aspect of the present invention, a semiconductor memory device has: a semiconductor layer formed on an insulating film; and a memory cell array including a matrix arrangement of a plurality of memory cells each made up of first and second transistors connected in series, one side of each memory cell being connected to a bit line and the other side of each memory cell being supplied with a reference potential, and according to another aspect of the present invention, a semiconductor memory device manufacturing method includes: forming an oxide layer and a silicon active layer on a semiconductor substrate; forming an element isolation region for separating said silicon active layer into discrete element-forming regions to be substantially flush with said silicon active layer; forming gate electrode of paired two transistors by depositing a gate electrode material on said silicon active layer and patterning it; injecting predetermined ions into a region for forming a diffusion layer in, using sa

Abstract: A multi-input logic circuit (e.g. a 2-input NAND circuit) mounted on a semiconductor integrated circuit comprises a plurality of voltage-activated transistors which have the same channel conduction type and are electrically connected in series between a power supply terminal and an output terminal. A source region and a body region of at least the voltage-activated transistor connected to the output terminal are electrically connected and have substantially the same potential. The semiconductor integrated circuit has either an SOI or SOS structure.

Abstract: A semiconductor device includes a semiconductor layer provided on a semiconductor substrate with an insulating film interposed therebetween. A gate electrode is provided on the semiconductor layer with a gate insulating film interposed therebetween, and a pair of source/drain regions are formed in the semiconductor layer so as to hold a body region under the gate electrode therebetween. A control section supplies voltages to the source/drain regions. The control section supplies the body region in an OFF state and ON state with a first voltage and a second voltage different from the first voltage, respectively. The second voltage is set such that a potential of the body region in the OFF state is substantially the same as a potential of the body region in the ON state.

Abstract: A semiconductor device comprises: a semiconductor substrate; an insulating layer provided on said semiconductor substrate; a first semiconductor layer provided on said insulating layer; a plurality of openings penetrating said first semiconductor layer and said insulating layer and reaching said semiconductor substrate; and second semiconductor layers filling said openings by selective growth and connected to said semiconductor substrate, wherein areal sizes of said plurality of openings are substantially equal to each other.

Abstract: A semiconductor device comprises a semiconductor substrate having a first insulator, and a semiconductor channel region formed on the first insulator, wherein the semiconductor channel region comprising at least two first regions both having the first conductivity type, a second region of the conductivity type opposite to the first conductivity type, the second region being provided between the two first regions, a second insulator formed on the second region, a gate electrode formed on the second insulator, a third region having the same conductivity type as that of the second region, the third region being electrically conductive to the second region, a third insulator formed on the third region, the third insulator having a width narrower than the widths of an isolation region for isolating the semiconductor formation region, and a fourth region of the same conductivity type as that of the third region, the fourth region being electrically conductive to the third region.

Abstract: A semiconductor device comprises a semiconductor substrate having a first insulator, and a semiconductor channel region formed on the first insulator, wherein the semiconductor channel region comprising at least two first regions both having the first conductivity type, a second region of the conductivity type opposite to the first conductivity type, the second region being provided between the two first regions, a second insulator formed on the second region, a gate electrode formed on the second insulator, a third region having the same conductivity type as that of the second region, the third region being electrically conductive to the second region, a third insulator formed on the third region, the third insulator having a width narrower than the widths of an isolation region for isolating the semiconductor formation region, and a fourth region of the same conductivity type as that of the third region, the fourth region being electrically conductive to the third region.

Abstract: A semiconductor device comprises a semiconductor substrate having a first insulator, and a semiconductor channel region formed on the first insulator, wherein the semiconductor channel region comprising at least two first regions both having the first conductivity type, a second region of the conductivity type opposite to the first conductivity type, the second region being provided between the two first regions, a second insulator formed on the second region, a gate electrode formed on the second insulator, a third region having the same conductivity type as that of the second-region, the third region being electrically conductive to the second region, a third insulator formed on the third region, the third insulator having a width narrower than the widths of an isolation region for isolating the semiconductor formation region, and a fourth region of the same conductivity type as that of the third region, the fourth region being electrically conductive to the third region.

Abstract: In a bipolar transistor improved to exhibit an excellent high-frequency property by decreasing the width of the intrinsic base with without increasing the base resistance, an emitter region, intrinsic base region and collector region are closely aligned on an insulating layer, and the intrinsic base region and the collector region make a protrusion projecting upward from the substrate surface. The protrusion has a width wider than the width of the intrinsic base region.

Abstract: A semiconductor device comprises a semiconductor substrate having a first insulator, and a semiconductor channel region formed on the first insulator, wherein the semiconductor channel region comprising at least two first regions both having the first conductivity type, a second region of the conductivity type opposite to the first conductivity type, the second region being provided between the two first regions, a second insulator formed on the second region, a gate electrode formed on the second insulator, a third region having the same conductivity type as that of the second region, the third region being electrically conductive to the second region, a third insulator formed on the third region, the third insulator having a width narrower than the widths of an isolation region for isolating the semiconductor formation region, and a fourth region of the same conductivity type as that of the third region, the fourth region being electrically conductive to the third region.

Abstract: A multi-input logic circuit (e.g. a 2-input NAND circuit) mounted on a semiconductor integrated circuit comprises a plurality of voltage activated transistors which have the same channel conduction type and are electrically connected in series between a power supply terminal and an output terminal. A source region and a body region of at least the voltage activated transistor connected to the output terminal are electrically connected and have substantially the same potential. The semiconductor integrated circuit has either an SOI or SOS structure.

Abstract: In a bipolar transistor improved to exhibit an excellent high-frequency property by decreasing the width of the intrinsic base with without increasing the base resistance, an emitter region, intrinsic base region and collector region are closely aligned on an insulating layer, and the intrinsic base region and the collector region make a protrusion projecting upward from the substrate surface. The protrusion has a width wider than the width of the intrinsic base region.

Abstract: In a lateral bipolar transistor, its emitter region, base region, link base region, and so forth, are made in self alignment with side walls of masks by using partly overlapping two mask patterns. Therefore, not relying on the mask alignment accuracy, these regions are made in a precisely controlled positional relation. Thus, the lateral bipolar transistor, thus obtained, is reduced in parasitic resistance of the base and parasitic junction capacitance between the emitter and the base, and alleviated in variance of characteristics caused by fluctuation of the length of a link base region, length of the emitter-base junction and relative positions of the emitter and the collector, and can be manufactured with a high reproducibility.

Abstract: An SOI-type MISFET with a body contact has a Si active layer arranged on an insulating layer. A pair of source and drain regions interposing a main channel region are arranged in the active layer. An additional channel region and a body-contact region are also arranged in the active layer. A gate electrode is arranged to have first and second portions facing the main and additional channel regions, respectively, through a gate insulating film. A main MIS capacitor and a parasitic MIS capacitor are formed under the first and second portions of the gate electrode, respectively. The additional channel region is doped with an impurity under a condition different from that of the main channel region such that electrical charges necessary for charging and discharging the parasitic MIS capacitor are decreased, in an operation voltage range of the device.

Abstract: The present invention provides a semiconductor device which includes a substrate having a projection-shaped semiconductor element region, a gate electrode formed through a gate insulating film on the upper face and side face of the element region, and a first conductivity type source region and drain region provided in a manner to form a channel region on the upper face of the element region across the gate electrode, and which has a high concentration impurity region containing a second conductivity type impurity at a concentration higher than that on the surface of the channel region in the central part of the projection-shaped semiconductor element region.