Abstract: The present invention relates to a phenoxypropylamine compound of the formula (I) 1

Abstract: A semiconductor device having a low channel resistance without degrading transistor characteristics even for the 0.1 &mgr;m generation or later, and also: a manufacturing method of the device. The method includes fabricating source/drain electrodes and a gate electrode without using selective metal growth methods. Further, after forming the gate electrode, a semiconductor film is temporarily formed selectively in source/drain regions. A dielectric film is next deposited on the substrate and then, the surface is etched by chemical/mechanical polish (CMP) techniques to the extent that the semiconductor film is exposed on the surface. The semiconductor film is then partly etched until its midway portion along the thickness is removed. Thereafter, a desired metal or silicide is deposited on the entire surface. Next, CMP etching is performed to form electrodes, while letting the electrodes reside on or over the source/drain semiconductor layers and a gate insulation layer.

Abstract: The present invention relates to a phenoxypropylamine compound of the formula (I) wherein each symbol is as defined in the specification, an optically active compound thereof or a pharmaceutically acceptable salt thereof and hydrates thereof, which simultaneously show selective affinity for and antagonistic activity against 5-HT1A receptor, as well as 5-HT reuptake inhibitory activity, and can be used as antidepressants quick in expressing an anti-depressive effect.

Abstract: A semiconductor device comprises a semiconductor substrate, a first circuit formed on the substrate, and a second circuit connected to the first circuit as an input/output portion thereof and powered by a voltage higher than that for the first circuit, the first circuit including a first and a second field-effect transistor, the first drain region of the first transistor accompanying a first load capacitance, the second drain region of the second transistor accompanying a second load capacitance smaller than the first load capacitance, and the first gate insulation film of the first transistor having an average relative dielectric constant higher than that of the second gate insulation film of the second transistor, thereby realizing a high operation speed.

Abstract: In a MIS transistor, the top surfaces of source/drain regions (S/D diffusion layers) formed on a semiconductor substrate 1 are arranged nearer to a gate electrode than a channel plane on the semiconductor substrate, and the top surfaces of the source/drain regions are arranged nearer than the channel plane than the interface between a gate insulator film provided on the upper side of the channel plane and the gate electrode. In this transistor, a groove is selectively formed in the surface of the semiconductor substrate, and a polycrystalline silicon deposited in the groove may be used as a mask to form impurity diffusion layers serving as source/drain regions to laminate and form a gate insulator film of a high dielectric film and a gate electrode. Alternatively, the polycrystalline silicon may be selectively formed to be used as a mask to elevate and form the impurity diffusion layer to laminate and form the gate insulator film and the gate electrode.

Abstract: A semiconductor device and a method of manufacturing the semiconductor device are disclosed. A semiconductor device of one of several disclosed embodiments comprises a semiconductor layer having a source region and a drain region, and a gate insulating film provided on the semiconductor layer between the source region and the drain region. The gate insulating film comprising an oxide including a metal element and further includes at least one element selected from the group consisting of nitrogen and aluminum as a first element. The content of the first element is relatively higher at both ends near the source region and the drain region than at a center of the gate insulating film. A gate electrode is provided on the gate insulating film.

Abstract: There is disclosed a MIS field effect transistor, comprising a silicon substrate, an insulating film formed over the silicon substrate and containing silicon and at least one of nitrogen and oxygen, a metal oxynitride film formed on the insulating film and containing at least one kind of metal atom selected from the group consisting of zirconium, hafnium and a lanthanoide series metal, the metal oxynitride film containing nitrogen atom not bonding with the metal atom without metal-nitrogen bond at the density of higher than 1019/cm3, and a gate electrode formed on the metal oxynitride film.

Abstract: There is disclosed a MIS field effect transistor, comprising a silicon substrate, an insulating film formed over the silicon substrate and containing silicon and at least one of nitrogen and oxygen, a metal oxynitride film formed on the insulating film and containing at least one kind of metal atom selected from the group consisting of zirconium, hafnium and a lanthanide series metal, the metal oxynitride film containing nitrogen atom not bonding with the metal atom without metal-nitrogen bond at the density of higher than 1019/cm3, and a gate electrode formed on the metal oxynitride film.

Abstract: The present invention provides a commercially profitable process for producing a &bgr;-amino acid ester derivative

Abstract: A semiconductor device having a low channel resistance without degrading transistor characteristics even for the 0.1 &mgr;m generation or later, and also: a manufacturing method of the device. The method includes fabricating source/drain electrodes and a gate electrode without using selective metal growth methods. Further, after forming the gate electrode, a semiconductor film is temporarily formed selectively in source/drain regions. A dielectric film is next deposited on the substrate and then, the surface is etched by chemical/mechanical polish (CMP) techniques to the extent that the semiconductor film is exposed on the surface. The semiconductor film is then partly etched until its midway portion along the thickness is removed. Thereafter, a desired metal or silicide is deposited on the entire surface. Next, CMP etching is performed to form electrodes, while letting the electrodes reside on or over the source/drain semiconductor layers and a gate insulation layer.

Abstract: There is disclosed a method of manufacturing a semiconductor device, wherein a thin film containing a metal and capable of bonding with oxygen is deposited on a silicon substrate, a metal oxide film is formed on the thin film, and the thin film is oxidized by heat treatment to form a gate insulating film comprising the oxidized thin film and the metal oxide film.

Abstract: In the first aspect of the invention, a semiconductor device can effectively suppress the adverse short channel effect and the possible occurrence of junction leak current and has a low resistance diffusion layer to realize a short propagation delay time as a plurality of side wall films 4, 5 are formed at least in a part of the area between the gate electrode 3 and an elevated region 8 by laying a plurality of films in an appropriate order.

Abstract: The present invention is intended to provide a semiconductor device having a gate electrode free from increasing of resistance of the gate electrode, from decreasing of capacitance of the insulation film due to depletion, and from penetrating of impurity. The semiconductor device comprises a silicon layer, a gate insulating film formed on the silicon layer, a metal boron compound layer formed on the gate insulating film, and a gate electrode formed on the metal boron compound layer and containing at least silicon.

Abstract: The present invention provides a commercially profitable process for producing a &bgr;-amino acid ester derivative which comprises reacting an &agr;-amino acid ester derivative with a base and a dihalomethane, reacting the same with a lithium amide and an alkyllithium in succession, and treating the reaction product with an acid in an alcohol.

Abstract: A semiconductor device having a low channel resistance without degrading transistor characteristics even for the 0.1 &mgr;m generation or later, and also: a manufacturing method of the device. The method includes fabricating source/drain electrodes and a gate electrode without using selective metal growth methods. Further, after forming the gate electrode, a semiconductor film is temporarily formed selectively in source/drain regions. A dielectric film is next deposited on the substrate and then, the surface is etched by chemical/mechanical polish (CMP) techniques to the extent that the semiconductor film is exposed on the surface. The semiconductor film is then partly etched until its midway portion along the thickness is removed. Thereafter, a desired metal or silicide is deposited on the entire surface. Next, CMP etching is performed to form electrodes, while letting the electrodes reside on or over the source/drain semiconductor layers and a gate insulation layer.

Abstract: This invention provides a process for producing optically active 2-[6-(hydroxymethyl)-1,3-dioxan-4-yl]acetic acid derivatives, which are of value as intermediates of drugs, from inexpensive starting materials without using any special equipment such as that required for super-low temperature reactions.

Abstract: An electrical wiring structure capable of improving a wiring delay to thereby achieve both low power consumption and high-speed performances without accompanying any significant changes in circuit layout and wiring structure of prior known CMOS logic circuitry and also alterations of the multilayer configuration of wiring layers is provided. A local wiring 1 and global wirings 2, 3 are stacked over a semiconductor substrate 10 in this order of sequence when looked at from lower part in a lamination direction, with dielectric layers sandwiched between adjacent ones of these layers. A distance between the local wiring 1 and the global wiring 2 is so formed as to be greater than a distance between the global wiring layer 2 and the global wiring, 3. Thus provided is a semiconductor device featured in that a drive voltage used to drive the global wirings 2, 3 is potentially lower than a drive voltage for driving inside of the local wiring 1.

Abstract: An electrical wiring structure capable of improving a wiring delay to thereby achieve both low power consumption and high-speed performances without accompanying any significant changes in circuit layout and wiring structure of prior known CMOS logic circuitry and also alterations of the multilayer configuration of wiring layers is provided. A local wiring 1 and global wirings 2, 3 are stacked over a semiconductor substrate 10 in this order of sequence when looked at from lower part in a lamination direction, with dielectric layers sandwiched between adjacent ones of these layers. A distance between the local wiring 1 and the global wiring 2 is so formed as to be greater than a distance between the global wiring layer 2 and the global wiring 3. Thus provided is a semiconductor device featured in that a drive voltage used to drive the global wirings 2, 3 is potentially lower than a drive voltage for driving inside of the local wiring 1.

Abstract: A process for producing optically active cysteine derivatives with high optical purity and good quality which is economically advantageous and is high in productivity even on a commercial scale is provided.

Abstract: An electrical wiring structure capable of improving a wiring delay to thereby achieve both low power consumption and high-speed performances without accompanying any significant changes in circuit layout and wiring structure of prior known CMOS logic circuitry and also alterations of the multilayer configuration of wiring layers is provided.