Abstract: At present, Cu (copper) is being used as a wiring material. In an RF-CMOS device as a combination of an RF analog device and CMOS logic device, two electrodes of a MIM capacitor are formed from Cu having a large diffusion coefficient. To prevent Cu from diffusing to the capacitor insulating film of the MIM capacitor, diffusion prevention films having a function of preventing diffusion of Cu are interposed between the capacitor insulating film and the two electrodes. As a result, Cu forming the electrodes does not diffuse to the capacitor insulating film.

Abstract: A semiconductor device comprises: a p-type semiconductor substrate (1); an insulating film (3); a gate electrode (2) formed on the substrate via the insulating film; and an n-type source/drain region (5) formed on both sides of a channel forming region (4) located under the gate electrode (2) formed on the substrate (1). In particular, the thickness (TOX) of the insulating film (3) is determined to be less than 2.5 nm at conversion rate of silicon oxide film (silicon oxide equivalent thickness); a gate length (Lg) of the electrode (2) is determined to be equal to or less than 0.3 &mgr;m; and further a voltage applied to the gate electrode (2) and the drain region (6) is determined to be 1.5 V or less. Therefore, in the MOSFET having the tunneling gate oxide film (3), the reliability of the transistor under the hot carrier stress can be improved, and the gate leakage current can be reduced markedly, so that the transistor characteristics can be improved markedly.

Abstract: The capacitor dielectric film (35) and the poly silicon layer (36) are formed on the silicide film (32) of the upper electrode LE of the capacitor. Further, after the Ti and TiN layer (37) has been formed on the poly silicon layer (36) by spattering, the formed Ti and TiN layer (37) is allowed to react upon the poly silicon layer (36), to form the TiSi.sub.2 layer (38) of high melting point silicide film on the poly silicon layer (36). After that, before forming the barrier layer (40) and the wiring layer (42), the substrate (10) is cleaned as pre-processing by applying a voltage to the substrate (10). In this cleaning process, since the capacitor dielectric film (35) is protected by the TiSi.sub.2 layer (38) of high melting point silicide film, it is possible to prevent the capacitor dielectric film (35) from being damaged during the cleaning process.

Abstract: A semiconductor device comprises: a p-type semiconductor substrate (1); an insulating film (3); a gate electrode (2) formed on the substrate via the insulating film; and an n-type source/drain region (5) formed on both sides of a channel forming region (4) located under the gate electrode (2) formed on the substrate (1). In particular, the thickness (T.sub.OX) of the insulating film (3) is determined to be less than 2.5 nm at conversion rate of silicon oxide film (silicon oxide equivalent thickness); a gate length (L.sub.g) of the gate electrode (2) is determined to be equal to or less than 0.3 .mu.m; and further a voltage applied to the gate electrode (2) and the drain region (6) is determined to be 1.5 V or less. Therefore, in the MOSFET having the tunneling gate oxide film (3), the reliability of the transistor under the hot carrier stress can be improved, and the gate leakage current can be reduced markedly, so that the transistor characteristics can be improved markedly.

Abstract: A semiconductor device capable of restraining a short channel effect and obtaining a current drivability that is as high as possible includes a semiconductor substrate, a gate insulating film formed on the surface of this substrate, a gate electrode formed on this gate insulating film and side wall insulating films formed on this gate electrode and along side walls of the gate insulating film. The semiconductor device further includes side wall conductor films formed adjacent to the side wall insulating films and a source/drain region formed in a surface region of the substrate under the side wall conductivity film and in a surface region, adjacent to the side wall conductivity film, of the semiconductor substrate. An impurity concentration in a depthwise direction of the substrate with the surface of the side wall conductor film serving as a starting point exhibits one maximum value in a predetermined depth but decreases in a portion deeper than the predetermined depth.

Abstract: A MOS type semiconductor device has a gate whose length is 170 nm (0.17 .mu.m) or less, a junction depth of source and drain diffusion layers in the vicinity of a channel is 22 nm or less, and a concentration of impurities at the surface in the source and drain diffusion layers is made to 10.sup.20 cm.sup.-3 or more. Such structure is obtained using solid phase diffusion using heat range from 950.degree. C. to 1050.degree. C. and/or narrowing gate width by ashing or etching. The other MOS type semiconductor device is characterized in that the relationship between the junction depth x.sub.j ?nm! in the source and drain diffusion layer regions and the effective channel length L.sub.eff ?nm! is determined by L.sub.eff >0.69 x.sub.j -6.17.

Abstract: A diffused server as a source and a drain. It is formed comprised of a deep first diffused layer and a shallow second diffused layer positioned between the first diffused layer and the channel region. In the second diffused region, a distribution in a depth direction of carriers has a profile in which the concentration is more than 5.times.10.sup.18 cm-.sup.-3 at the peak and is in correspondence with a carrier concentration of the semiconductor substrate at a depth less than 0.04 .mu.m. Since the second diffused layer has a high concentration, the short-channel effect can be suppressed. As the second diffused region, a solid phase diffusion source such as an impurity doped silicate glass is used.

Abstract: A semiconductor device capable of restraining a short channel effect and obtaining a current drivability that is as high as possible includes a semiconductor substrate, a gate insulating film formed on the surface of this substrate, a gate electrode formed on this gate insulating film and side wall insulating films formed on this gate electrode and along side walls of the gate insulating film. The semiconductor device further includes side wall conductor films formed adjacent to the side wall insulating films and a source/drain region formed in a surface region of the substrate under the side wall conductivity film and in a surface region, adjacent to the side wall conductivity film, of the semiconductor substrate. An impurity concentration in a depthwise direction of the substrate with the surface of the side wall conductor film serving as a starting point exhibits one maximum value in a predetermined depth but decreases in a portion deeper than the predetermined depth.

Abstract: A diffused layer serves as a source and a drain. It is formed comprised of a deep first diffused layer and a shallow second diffused layer positioned between the first diffused layer and the channel region. In the second diffused region, a distribution in a depth direction of carriers has a profile in which the concentration is more than 5.times.10.sup.18 cm.sup.-3 at the peak and is in correspondence with a carrier concentration of the semiconductor substrate at a depth less than 0.04 .mu.m. Since the second diffused layer has a high concentration, the short-channel effect can be suppressed. As the second diffused region, a solid phase diffusion source such as an impurity doped silicate glass is used.

Abstract: A semiconductor device including a CMOSFET having first and second channel type MOSFETs, respectively formed in a first semiconductor region of a first conductivity type and in a second semiconductor region of a second conductivity type. The first channel type MOSFET has a first gate electrode insulatively formed on the first region, made of a first conductivity type semiconductor, and having a gate length of 0.2 .mu.m or less, first source/drain regions of the second conductivity type respectively formed in the first region and having a LDD structure, and a buried channel region of the second conductivity type formed just below the first gate electrode. The second channel type MOSFET has a second gate electrode insulatively formed on the second region, made of a first conductivity type semiconductor, and having a gate length of 0.2 .mu.m or less, second source/drain regions of the first conductivity type respectively formed in the second region and having a LDD structure.

Abstract: A MOS type semiconductor device has a gate whose length is 170 nm (0.17 .mu.m) or less, a junction depth of source and drain diffusion layers in the vicinity of a channel is 22 nm or less, and a concentration of impurities at the surface in the source and drain diffusion layers is made to 10.sup.20 cm.sup.-3 or more. Such structure is obtained using solid phase diffusion using heat range from 950.degree. C. to 1050.degree. C. and/or narrowing gate width by ashing or etching. The other MOS type semiconductor device is characterized in that the relationship between the junction depth x.sub.j ?nm! in the source and drain diffusion layer regions and the effective channel length L.sub.eff ?nm! is determined by L.sub.eff >0.69 x.sub.j -6.17.

Abstract: A data processing apparatus which includes a display unit and a power supply controller for supplying power to the display unit. The display unit has a display screen and a back light controller. The power supply controller comprises a switch, at least one output line for receiving the power from the switch and for supplying therethrough the power to electronic devices, a delay circuit for receiving the power from the switch and when the switch is turned ON to start supply of the power, for outputting the power after passage of a predetermined time from the start of the power supply, and a second output line for supplying the power from the delay circuit to the back light controller therethrough.

Abstract: A diffused layer serves as a source and a drain. It is formed comprised of a deep first diffused layer and a shallow second diffused layer positioned between the first diffused layer and the channel region. In the second diffused region, a distribution in a depth direction of carriers has a profile in which the concentration is more than 5.times.10.sup.18 cm.sup.-3 at the peak and is in correspondence with a carrier concentration of the semiconductor substrate at a depth less than 0.04 .mu.m. Since the second diffused layer has a high concentration, the short-channel effect can be suppressed. As the second diffused region, a solid phase diffusion source such as an impurity doped silicate glass is used.

Abstract: A process for the production of a fiber-reinforced composite material, which comprises the steps of(1) preparing a polymeric composition containing a substantially linear aromatic oligomer having a terminal aliphatic hydroxyl group, bis(acylcaprolactam) and a catalyst which promotes a ring opening-addition reaction of a hydroxyl group and a caprolactam ring,(2) melting the polymeric composition and impregnating it into a fibrous reinforcing material to form a impregnated product, and(3) heating the impregnated product up to a temperature sufficient to open the caprolactam ring while inhibiting elimination of caprolactam thereby to form, as a matrix resin, a thermoplastic copolymer having an ester group and an amide group in its main chain;and a fiber-reinforced composition material produced by the above-mentioned process.