A semiconductor device includes a source region, a drain region, and a gate dielectric layer formed on a substrate; a gate electrode formed on the gate dielectric layer; a first dielectric pattern, formed contacting a sidewall of the gate electrode, extending from the source region to a portion of an upper surface of the gate electrode; a spacer formed on another sidewall of the gate electrode between the gate electrode and the drain region; and a gate silicide layer formed between the first dielectric pattern and the spacer.

A semiconductor device includes a substrate, a metal gate and a poly gate. The substrate includes a first region and a second region. The metal gate is disposed on the first region of the substrate. The poly gate is disposed on the second region of the substrate. A gate area of the poly gate is greater than that of the metal gate.

An MISFET has a gate electrode formed on a semiconductor substrate via a gate insulating film, and a source region and a drain region formed inside the semiconductor substrate so as to sandwich the gate electrode. And, a first silicide layer is formed on surfaces of the source region and the drain region, and a second silicide layer is formed on a surface of the gate electrode. Each of the first silicide layer and the second silicide layer is made of a first metal and silicon, and further contains a second metal different from the first metal. And, a concentration of the second metal inside the second silicide layer is lower than a concentration of the second metal inside the first silicide layer.

Reliability of a semiconductor device is improved, and use efficiency of a sputtering apparatus is increased. When depositing thin films over a main surface of a semiconductor wafer using a magnetron sputtering apparatus in which a collimator is installed in a space between the semiconductor wafer and a target installed in a chamber, a region inner than a peripheral part of the collimator is made thinner than the peripheral part. Thus, it becomes possible to suppress deterioration in uniformity of the thin film in a wafer plane, which may occur as the integrated usage of the target increases.

A semiconductor device includes a semiconductor body of a wide-bandgap semiconductor material. A plurality of first bond areas is connected to a first load terminal of the semiconductor device. First gate fingers are arranged between the first bond areas. The first gate fingers extend in a first lateral direction and branch off from at least one of a first gate line portion and a second gate line portion. Second gate fingers extend in the first lateral direction. A first length of any of the first gate fingers along the first lateral direction is greater than a second length of any of the second gate fingers along the first lateral direction. A sum of the first length and the second length is equal to or greater than a lateral distance between the first gate line portion and the second gate line portion along the first lateral direction.

An integrated circuit containing a first plurality of MOS transistors operating in a low voltage range, and a second plurality of MOS transistors operating in a mid voltage range, may also include a high-voltage MOS transistor which operates in a third voltage range significantly higher than the low and mid voltage ranges, for example 20 to 30 volts. The high-voltage MOS transistor has a closed loop configuration, in which a drain region is surrounded by a gate, which is in turn surrounded by a source region, so that the gate does not overlap field oxide. The integrated circuit may include an n-channel version of the high-voltage MOS transistor and/or a p-channel version of the high-voltage MOS transistor. Implanted regions of the n-channel version and the p-channel version are formed concurrently with implanted regions in the first and second pluralities of MOS transistors.

In an embodiment, a wide bandgap semiconductor power device, includes a wide bandgap semiconductor substrate layer; an epitaxial semiconductor layer disposed above the wide bandgap semiconductor substrate layer; a gate dielectric layer disposed directly over a portion of the epitaxial semiconductor layer; and a gate electrode disposed directly over the gate dielectric layer. The gate electrode includes an in-situ doped semiconductor layer disposed directly over the gate dielectric layer and a metal-containing layer disposed directly over the in-situ doped semiconductor layer.

An embodiment relates to a n-type planar gate DMOSFET comprising a Silicon Carbide (SiC) substrate. The SiC substrate includes a N+ substrate, a N− drift layer, a P-well region and a first N+ source region within each P-well region. A second N+ source region is formed between the P-well region and a source metal via a silicide layer. During third quadrant operation of the DMOSFET, the second N+ source region starts depleting when a source terminal is positively biased with respect to a drain terminal. The second N+ source region impacts turn-on voltage of body diode regions of the DMOSFET by establishing short-circuitry between the P-well region and the source metal when the second N+ source region is completely depleted.

A metal-oxide-semiconductor field-effect transistor (MOSFET) power device includes an active region formed on a bulk semiconductor substrate, the active region having a first conductivity type formed on at least a portion of the bulk semiconductor substrate. A first terminal is formed on an upper surface of the structure and electrically connects with at least one other region having the first conductivity type formed in the active region. A buried well having a second conductivity type is formed in the active region and is coupled with a second terminal formed on the upper surface of the structure. The buried well and the active region form a clamping diode which positions a breakdown avalanche region between the buried well and the first terminal. A breakdown voltage of at least one of the power devices is a function of characteristics of the buried well.

A method of forming a semiconductor device includes recessing the upper surface of first and second areas of a semiconductor substrate relative to the third area of the substrate, forming a pair of stack structures in the first area each having a control gate over a floating gate, forming a first source region in the substrate between the pair of stack structures, forming an erase gate over the first source region, forming a block of dummy material in the third area, forming select gates adjacent the stack structures, forming high voltage gates in the second area, forming a first blocking layer over at least a portion of one of the high voltage gates, forming silicide on a top surface of the high voltage gates which are not underneath the first blocking layer, and replacing the block of dummy material with a block of metal material.