Abstract: Improvements are achieved in the characteristics of a semiconductor device including SRAM memory cells. Under an active region in which an access transistor forming an SRAM is disposed, a p-type semiconductor region is disposed via an insulating layer such that the bottom portion and side portions thereof come in contact with an n-type semiconductor region. Thus, the p-type semiconductor region is pn-isolated from the n-type semiconductor region, and the gate electrode of the access transistor is coupled to the p-type semiconductor region. The coupling is achieved by a shared plug which is an indiscrete conductive film extending from over the gate electrode of the access transistor to over the p-type semiconductor region. As a result, when the access transistor is in an ON state, a potential in the p-type semiconductor region serving as a back gate simultaneously increases to allow an increase in an ON current for the transistor.

Abstract: The performances of a semiconductor device are improved. The device includes a first MISFET in which hafnium is added to the gate electrode side of a first gate insulation film including silicon oxynitride, and a second MISFET in which hafnium is added to the gate electrode side of a second gate insulation film including silicon oxynitride. The hafnium concentration in the second gate insulation film of the second MISFET is set smaller than the hafnium concentration in the first gate insulation film of the first MISFET; and the nitrogen concentration in the second gate insulation film of the second MISFET is set smaller than the nitrogen concentration in the first gate insulation film of the first MISFET. As a result, the threshold voltage of the second MISFET is adjusted to be smaller than the threshold voltage of the first MISFET.

Abstract: A semiconductor device having an n channel MISFET formed on an SOI substrate including a support substrate, an insulating layer formed on the support substrate and a silicon layer formed on the insulating layer has the following structure. An impurity region for threshold adjustment is provided in the support substrate of a gate electrode so that the silicon layer contains carbon. The threshold value can be adjusted by the semiconductor region for threshold adjustment in this manner. Further, by providing the silicon layer containing carbon, even when the impurity of the semiconductor region for threshold adjustment is diffused to the silicon layer across the insulating layer, the impurity is inactivated by the carbon implanted into the silicon layer. As a result, the fluctuation of the transistor characteristics, for example, the fluctuation of the threshold voltage of the MISFET can be reduced.

Abstract: There are provided a semiconductor device which can be miniaturized without being deteriorated in characteristics, and a manufacturing method thereof. The semiconductor device includes a semiconductor substrate having a main surface, a source region and a drain region formed apart from each other in the main surface, a gate electrode layer formed over the main surface sandwiched between the source region and the drain region, a first conductive layer formed so as to be in contact with the surface of the source region, and a second conductive layer formed so as to be in contact with the surface of the drain region. A recess is formed in the main surface so as to extend from the contact region between the first conductive layer and the source region through a part underlying the gate electrode layer to the contact region between the second conductive layer and the drain region.

Abstract: A semiconductor device is manufactured by using an SOI substrate having an insulating layer on a substrate and a semiconductor layer on the insulating layer. The semiconductor device is provided with a gate electrode formed on the semiconductor layer via a gate insulating film, a sidewall spacer formed on a sidewall of the gate electrode, a semiconductor layer for source/drain that is epitaxially grown on the semiconductor layer, and a sidewall spacer formed on a sidewall of the semiconductor layer.

Abstract: Provided is a semiconductor device having an insulating gate field effect transistor equipped with a metal oxide film in a portion, on the side of a source region, between a gate insulating film and a gate electrode. The metal oxide film is provided above a p+ type semiconductor region for punch-through stopper so as to cover the entire region thereof. Such a metal oxide film contributes to a decrease in the impurity concentration of the p+ type semiconductor region, making it possible to reduce variations in the threshold voltage of the transistor. On the side of a drain region, the gate insulating film is formed as a single film without stacking the metal oxide film thereon. As a result, the resulting transistor can escape deterioration in reliability which will otherwise occur due to hot carriers on the side of the end of the drain region.

Abstract: A bulk & SOI hybrid CMIS device, in which an I/O bulk part and a core logic SOI part are mounted, needs a number of gate stacks to optimize threshold voltage control and causes a problem that the process and structure become complicated. The present invention adjusts the threshold voltage of MISFET at the corresponding part by introducing impurities into any of back gate semiconductor regions, in an SOI semiconductor CMISFET integrated circuit device having a high-k gate insulating film and a metal gate electrode.

Abstract: On a semiconductor substrate having an SOI region and a bulk silicon region formed on its upper surface, epitaxial layers are formed in source and drain regions of a MOSFET formed in the SOI region, and no epitaxial layer is formed in source and drain regions of a MOSFET formed in the bulk silicon region. By covering the end portions of the epitaxial layers with silicon nitride films, even when diffusion layers are formed by implanting ions from above the epitaxial layers, it is possible to prevent the impurity ions from being implanted down to a lower surface of a silicon layer.

Abstract: A method for manufacturing a semiconductor integrated circuit device includes the step of forming an SOI device region and a bulk device region on an SOI type semiconductor wafer. The method includes: removing a BOX layer and an SOI layer in a bulk device region; and thereafter forming an STI region in both the SOI device region and the bulk device region. In the method, the STI region in the SOI device region is formed to extend through the BOX layer.

Abstract: a method for producing a semiconductor device provided in such a manner that a first layer and a second layer are laminated to ensure that their TSVs are arranged in almost a straight line, including: first layer production steps including steps of preparing a substrate, forming a transistor of an input/output circuit on an upper surface of the substrate, forming an insulation layer so as to cover the transistor, and forming a TSV in the insulation layer; second layer production steps including steps of preparing a substrate, forming a transistor of a logic circuit on an upper surface of the substrate, forming an insulation layer so as to cover the transistor, and forming a TSV in the insulation layer; a connection step of connecting surfaces of the first layer and the second layer on a side opposite to substrates of the first layer and the second layer to ensure that the TSV of the first layer and the TSV of the second layer are arranged in almost a straight line; and a step of removing the substrate of the

Abstract: To provide a technique capable of achieving improvement of the parasitic resistance in FINFETs. In the FINFET in the present invention, a sidewall is formed of a laminated film. Specifically, the sidewall is composed of a first silicon oxide film, a silicon nitride film formed over the first silicon oxide film, and a second silicon oxide film formed over the silicon nitride film. The sidewall is not formed on the side wall of a fin. Thus, in the present invention, the sidewall is formed on the side wall of a gate electrode and the sidewall is not formed on the side wall of the fin.

Abstract: A semiconductor device with an SRAM memory cell having improved characteristics. Below an active region in which a driver transistor including a SRAM is placed, an n type back gate region surrounded by an element isolation region is provided via an insulating layer. It is coupled to the gate electrode of the driver transistor. A p well region is provided below the n type back gate region and at least partially extends to a position deeper than the element isolation region. It is fixed at a grounding potential. Such a configuration makes it possible to control the threshold potential of the transistor to be high when the transistor is ON and to be low when the transistor is OFF; and control so as not to apply a forward bias to the PN junction between the p well region and the n type back gate region.

Abstract: In a semiconductor device, a body thick film transistor and a body thin film transistor having a different body film thickness are formed on the same SOI substrate (silicon support substrate, buried oxide film and silicon layer). The body film is formed to be relatively thick in the body thick film transistor, which has a recess structure where the level of the surface of the source/drain regions is lower than the level of the surface of the body region, and thus, the SOI film in the source/drain regions is formed to be as thin as the SOI film in the body thin film transistor. On the other hand, the entirety of the SOI film is formed to have a relatively thin film thickness in the body thin film transistor. In addition, the source/drain regions are formed to penetrate through the silicon layer.

Abstract: An object of the present invention is to provide a semiconductor device having a fin-type transistor that is excellent in characteristics by forming a fin-shaped semiconductor portion and a gate electrode with high precision or by making improvement regarding variations in characteristics among elements. The present invention is a semiconductor device including a fin-shaped semiconductor portion having a source region formed on one side thereof and a drain region formed on the other side thereof, and a gate electrode formed between the source region and the drain region to surround the fin-shaped semiconductor portion with a gate insulating film interposed therebetween. One solution for solving the problem according to the invention is that the gate electrode uses a metal material or a silicide material that is wet etchable.

Abstract: An object of the present invention is to provide a semiconductor device having a fin-type transistor that is excellent in characteristics by forming a fin-shaped semiconductor portion and a gate electrode with high precision or by making improvement regarding variations in characteristics among elements. The present invention is a semiconductor device including a fin-shaped semiconductor portion having a source region formed on one side thereof and a drain region formed on the other side thereof, and a gate electrode formed between the source region and the drain region to surround the fin-shaped semiconductor portion with a gate insulating film interposed therebetween. One solution for solving the problem according to the invention is that the gate electrode uses a metal material or a silicide material that is wet etchable.

Abstract: A bulk & SOI hybrid CMIS device, in which an I/O bulk part and a core logic SOI part are mounted, needs a number of gate stacks to optimize threshold voltage control and causes a problem that the process and structure become complicated. The present invention adjusts the threshold voltage of MISFET at the corresponding part by introducing impurities into any of back gate semiconductor regions, in an SOI semiconductor CMISFET integrated circuit device having a high-k gate insulating film and a metal gate electrode.

Abstract: There is provided an SOI-MISFET including: an SOI layer; a gate electrode provided on the SOI layer interposing a gate insulator; and a first elevated layer provided higher in height from the SOI layer than the gate electrode at both sidewall sides of the gate electrode on the SOI layer so as to constitute a source and drain. Further, there is also provided a bulk-MISFET including: a gate electrode provided on a silicon substrate interposing a gate insulator thicker than the gate insulator of the SOI MISFET; and a second elevated layer configuring a source and drain provided on a semiconductor substrate at both sidewalls of the gate electrode. The first elevated layer is thicker than the second elevated layer, and the whole of the gate electrodes, part of the source and drain of the SOI-MISFET, and part of the source and drain of the bulk-MISFET are silicided.

Abstract: Logic transistors (MOSFETs, MISFETs) in core portions of integrated circuits can be microminiaturized by scaling operating voltage as their generation advances. However, since transistors (MOSFETs, MISFETs) in high-breakdown voltage portions operate on relatively high power supply voltage, it is difficult to reduce their size. Similarly, electrostatic discharge (ESD) protection circuits in power supply cells protect the elements in a semiconductor integrated circuit against static electricity (foreign surge); therefore, they are indispensably required to be high in breakdown voltage and call for a large area for dissipating electric charges. To microminiaturize integrated circuits, therefore, a transistor structure that enables microminiaturization is indispensable.

Abstract: A finger length a1 of a transistor P11 is longer than a finger length A1 of a transistor P1, and a finger length b1 of a transistor N11 is longer than a finger length B1 of a transistor N1. The finger length b1 of the transistor N11 is shorter than the finger length A1 of the transistor P1, and the relation: a1>A1>b1>B1 is established. In a relation between an I/O section and a logic circuit section, as for MOS transistor of the same conductive type, a finger length of a MOS transistor constituting the logic circuit section is set so as to be longer than a finger length of a MOS transistor constituting the I/O section.

Abstract: A high breakdown voltage circuit containing a high breakdown voltage MOSFET in LSI, unlike a quintessential internal circuit, has an operating voltage fixed in a high state due to the relation with the outside and, therefore, miniaturization by the voltage lowering can not be applied, differing from ordinary cases. Consequently, the voltage lowering of an internal circuit part results in a furthermore enlargement of occupying area in the chip. The present inventors evaluated various measures for the problem, and made it clear that such problems as compatibility with the CMOSFET circuit configuration and device configuration, etc. constitute obstacles.