Abstract: Silicon carbide semiconductor devices and methods of fabricating silicon carbide semiconductor devices are provided by successively etching a mask layer to provide windows for formation of a source region of a first conductivity type, a buried silicon carbide region of a second conductivity type opposite to the first conductivity type and a second conductivity type well region in a first conductivity type silicon carbide layer. The source region and the buried silicon carbide region are formed utilizing a first window of the mask layer. Then, the well region is formed utilizing a second window of the mask layer, the second window being provided by a subsequent etch of the mask layer having the first window.

Abstract: According to one aspect of the invention, there is provided a semiconductor device fabrication method comprising: forming a gate insulating film on a semiconductor substrate; forming a film containing a predetermined semiconductor material and germanium on the gate insulating film; oxidizing the film to form a first film having a germanium concentration higher than that of the film and a film thickness smaller than that of the film on the gate insulating film, and form an oxide film on the first film; removing the oxide film; forming, on the first film, a second film containing the semiconductor material and having a germanium concentration lower than that of the first film; forming a gate electrode by etching the second and first films; and forming a source region and drain region by ion-implanting a predetermined impurity by using the gate electrode as a mask.

Abstract: One aspect of the present subject matter relates to a partially depleted silicon-on-insulator structure. The structure includes a well region formed above an oxide insulation layer. In various embodiments, the well region is a multilayer epitaxy that includes a silicon germanium (Si—Ge) layer. In various embodiments, the well region includes a number of recombination centers between the Si—Ge layer and the insulation layer. A source region, a drain region, a gate oxide layer, and a gate are formed. In various embodiments, the Si—Ge layer includes a number of recombination centers in the source/drain regions. In various embodiments, a metal silicide layer and a lateral metal Schottky layer are formed above the well region to contact the source region and the well region. Other aspects are provided herein.

Abstract: Methods for forming portions of source and drain (S/D) regions of a first ensuing transistor (40) to include a semiconductor material (47) having a different composition of non-dopant elements than portions of S/D regions (35) of a second ensuing transistor (30) of opposite conductivity type are provided. The methods additionally include forming another semiconductor material (48) upon at least one set of the S/D regions of the ensuing transistors such that S/D surface layers of the ensuing transistors include substantially the same composition of non-dopant elements. A resulting semiconductor topography includes a pair of CMOS transistors (30, 40) collectively having S/D region surfaces with substantially the same composition of non-dopant elements. The S/D regions of one transistor (40) of the pair of CMOS transistors includes an underlying layer (47) having a different composition of non-dopant elements than underlying layers of the S/D regions (35) of the other transistor (30).

Abstract: A method of manufacturing a semiconductor device includes forming a silicon germanium layer and a N-channel transistor and a P-channel transistor over the silicon germanium layer. A beta ratio of the N-channel transistor to the P-channel transistor is about 1.8 to about 2.2. A semiconductor device is also disclosed.

Abstract: Example embodiments relate to a gate electrode, a method of forming the gate electrode, a transistor having the gate electrode, a method of manufacturing the transistor, a semiconductor device having the transistor and a method of manufacturing the semiconductor device. The gate electrode may include an embossing structure including a metal or a metal compound and having a first work function and a conductive layer pattern having a second work function formed on the embossing structure. A work function of the gate electrode may be adjusted between a work function of the embossing structure and a work function of the conductive layer pattern formed on the embossing structure. An NMOS transistor and a PMOS transistor having different work functions respectively may be formed on a substrate.

Abstract: A Si/C superlattice useful for semiconductor devices comprises a plurality of epitaxially grown silicon layers alternating with carbon layers respectively adsorbed on surfaces of said silicon layers. Structures and devices comprising the superlattice and methods are described.