A semiconductor device and a method of manufacturing a semiconductor device are provided. The semiconductor device includes a semiconductor substrate and a word line structure. The semiconductor substrate has an active region. The word line structure is disposed in the active region of the semiconductor substrate. The word line structure includes a first work function layer, a second work function layer, and a buffer structure. The second work function layer is on the first work function layer. The buffer structure is between the first work function layer and the second work function layer.

A semiconductor device production method includes a first step of forming a planar silicon layer on a silicon substrate and forming first and second pillar-shaped silicon layers on the planar silicon layer; a second step of forming a gate insulating film around the first and second pillar-shaped silicon layers, forming a metal film and a polysilicon film around the gate insulating film, controlling a thickness of the polysilicon film to be smaller than a half of a distance between the first and second pillar-shaped silicon layers, depositing a resist, exposing the polysilicon film on side walls of upper portions of the first and second pillar-shaped semiconductor layers, etching-away the exposed polysilicon film, stripping the third resist, and etching-away the metal film; and a third step of forming a resist for forming a gate line and performing anisotropic etching to form a gate line and first and second gate electrodes.

A transistor device is provided that includes a substrate, a first channel region formed in a first portion of the substrate and being doped with a dopant of a first type of conductivity, a second channel region formed in a second portion of the substrate and being doped with a dopant of a second type of conductivity, a gate insulating layer formed on the first channel region and on the second channel region, a dielectric capping layer formed on the gate insulating layer, a first gate region formed on the dielectric capping layer over the first channel region, and a second gate region formed on the dielectric capping layer over the second channel region, wherein the first gate region and the second gate region are made of the same material, and wherein one of the first gate region and the second gate region comprises an ion implantation.

Disclosed is a semiconductor device having a memory cell which comprises a transistor having a control gate and a storage gate. The storage gate comprises an oxide semiconductor and is able to be a conductor and an insulator depending on the potential of the storage gate and the potential of the control gate. Data is written by setting the potential of the control gate to allow the storage gate to be a conductor, supplying a potential of data to be stored to the storage gate, and setting the potential of the control gate to allow the storage gate to be an insulator. Data is read by supplying a potential for reading to a read signal line connected to one of a source and a drain of the transistor and detecting the change in potential of a bit line connected to the other of the source and the drain.

Semiconductor devices may include a semiconductor substrate with a first semiconductor fin aligned end-to-end with a second semiconductor with a recess between facing ends of the first and second semiconductor fins. A first insulator pattern is formed adjacent sidewalls of the first and second semiconductor fins and a second insulator pattern is formed within the first recess. The second insulator pattern may have a top surface higher than a top surface of the first insulator pattern, such as to the height of the top surface of the fins (or higher or lower). First and second gates extend along sidewalls and a top surface of the first semiconductor fin. A dummy gate electrode may be formed on the top surface of the second insulator. Methods for manufacture of the same and modifications are also disclosed.

A method for fabricating a semiconductor device comprises forming a dummy gate on a substrate; forming spacers at opposing sides of the dummy gate; depositing a sacrificial interlayer dielectric over the dummy gate; planarizing the interlayer dielectric to expose the dummy gate; removing the dummy gate; forming a replacement metal gate with a protective cap between the spacers and on the substrate to replace the removed dummy gate; removing the sacrificial interlayer dielectric; siliciding exposed areas of the substrate adjacent to the replacement metal gate; depositing a final interlayer dielectric over the replacement metal gate and the exposed silicided areas; and forming vias through the final interlayer dielectric to the silicided areas.

Disclosed are CMOS device and CMOS inverter. The CMOS device includes a substrate having active lines extending in a first direction and defined by a device isolation layer, the substrate being divided into an NMOS area, a PMOS area and a boundary area interposed between the NMOPS and the PMOS areas and having the device isolation layer without the active line, a gate line extending in a second direction across the active lines and having a first gate structure on the active line in the first area, a second gate structure on the active line in the second and a third gate structure on the device isolation layer in the third area. The electrical resistance and parasitic capacitance of the third gate structure are smaller than those of the NMOS and the PMOS gate structures. Accordingly, better AC and DC performance of the CMOS device can be obtained.

When a semiconductor device including a transistor in which a gate electrode layer, a gate insulating film, and an oxide semiconductor film are stacked and a source and drain electrode layers are provided in contact with the oxide semiconductor film is manufactured, after the formation of the gate electrode layer or the source and drain electrode layers by an etching step, a step of removing a residue remaining by the etching step and existing on a surface of the gate electrode layer or a surface of the oxide semiconductor film and in the vicinity of the surface is performed. The surface density of the residue on the surface of the oxide semiconductor film or the gate electrode layer can be 110.sup.13 atoms/cm.sup.2 or lower.

The SiC epitaxial wafer includes a substrate, and an SiC epitaxial growth layer disposed on the substrate, wherein an Si compound gas is used for a supply source of Si, and a Carbon (C) compound gas is used as a supply source of C, for the SiC epitaxial growth layer, wherein any one or both of the Si compound gas and the C compound gas is provided with a compound gas containing Fluorine (F), as the supply source. The Si compound is generally expressed with Si.sub.nH.sub.xCl.sub.yF.sub.z (n>=1, x>=0, y>=0, z>=1, x+y+z=2n+2), and the C compound is generally expressed with C.sub.mH.sub.qCl.sub.rF.sub.s (m>=1, q>=0, r>=0, s>=1, q+r+s=2m+2) . There are provided a high quality SiC epitaxial wafer having few surface defects and having excellent film thickness uniformity and carrier density uniformity, a manufacturing apparatus of such an SiC epitaxial wafer, a fabrication method of such an SiC epitaxial wafer, and a semiconductor device.

A device includes a conductive layer including a bottom portion, and a sidewall portion over the bottom portion, wherein the sidewall portion is connected to an end of the bottom portion. An aluminum-containing layer overlaps the bottom portion of the conductive layer, wherein a top surface of the aluminum-containing layer is substantially level with a top edge of the sidewall portion of the conductive layer. An aluminum oxide layer is overlying the aluminum-containing layer. A copper-containing region is over the aluminum oxide layer, and is spaced apart from the aluminum-containing layer by the aluminum oxide layer. The copper-containing region is electrically coupled to the aluminum-containing layer through the top edge of the sidewall portion of the conductive layer.