A laterally diffused metal oxide semiconductor device includes: a substrate (10); a buried layer region (32) in the substrate; a well region (34) on the buried layer region (32); a gate region on the well region; a source region (41) and a drain region (43) which are located at two sides of the gate region; and a super junction structure. The source region (41) is located in the well region (34); the drain region (34) is located in the super junction structure; the gate region comprises a gate oxide layer and a gate electrode on the gate oxide layer; and the super junction structure comprises a plurality of N-columns and P-columns, wherein the N-columns and the P-columns are alternately arranged in a direction which is horizontal and is perpendicular to the direction of a connecting line between the source region and the drain region, each N-column comprises a top-layer N-region (23) and a bottom-layer N-region which are butted vertically, and each P-column comprises a top-layer P-region (24) and a bottom-layer P-region which are butted vertically.

A method of manufacturing a semiconductor device includes forming a second SiC layer of a first conductivity type on a first SiC layer by epitaxial growth, forming a first region of a second conductivity type by selectively ion-implanting first impurities of the second conductivity type into the second SiC layer, removing a portion of the first region, forming a third SiC layer of the first conductivity type on the second SiC layer by epitaxial growth, and forming a second region of the second conductivity type on the first region by selectively ion-implanting second impurities of the second conductivity type into the third SiC layer.

A vertical drift metal-oxide-semiconductor (VDMOS) transistor with improved contact to source and body regions, and a method of fabricating the same. A masked ion implant of the source regions into opposite-type body regions defines the locations of body contact regions, which are implanted subsequently with a blanket implant. The surface of the source regions and body contact regions are silicide clad, and an overlying insulator layer deposited and planarized. Contact openings are formed through the planarized insulator layer, within which conductive plugs are formed to contact the metal silicide, and thus the source and body regions of the device. A metal conductor is formed overall to the desired thickness, and contacts the conductive plugs to provide bias to the source and body regions.

An integrated circuit and method having an extended drain MOS transistor with a buried drift region, a drain diffused link, a channel diffused link, and an isolation link which electrically isolated the source, where the isolation diffused link is formed by implanting through segmented areas to dilute the doping to less than two-thirds the doping in the drain diffused link.

A semiconductor device includes an element portion and a gate pad portion on the same wide gap semiconductor substrate. The element portion includes a first trench structure having a plurality of first protective trenches and first buried layers formed deeper than gate trenches. The gate pad portion includes a second trench structure having a plurality of second protective trenches and second buried layers. The second trench structure is either one of a structure where the second trench structure includes: a p-type second semiconductor region and a second buried layer made of a conductor or a structure where the second trench structure includes a second buried layer formed of a metal layer which forms a Schottky contact. The second buried layer is electrically connected with the source electrode layer.

Semiconductor devices includes a thin epitaxial layer (nanotube) formed on sidewalls of mesas formed in a semiconductor layer. In one embodiment, a semiconductor device includes a first semiconductor layer, a second semiconductor layer formed thereon and of the opposite conductivity type, and a first epitaxial layer formed on mesas of the second semiconductor layer. An electric field along a length of the first epitaxial layer is uniformly distributed.

A transistor device includes: a first source region and a first drain region spaced apart from each other in a first direction of a semiconductor body; at least two gate regions arranged between the first source region and the first drain region and spaced apart from each other in a second direction of the semiconductor body; at least one drift region adjoining the first source region and electrically coupled to the first drain region; at least one compensation region adjoining the at least one drift region and the at least two gate regions; a MOSFET including a drain node connected to the first source region, a source node connected to the at least two gate region, and a gate node. Active regions of the MOSFET are integrated in the semiconductor body in a device region that is spaced apart from the at least two gate regions.

Various improvements in vertical transistors, such as IGBTs, are disclosed. The improvements include forming periodic highly-doped p-type emitter dots in the top surface region of a growth substrate, followed by growing the various transistor layers, followed by grounding down the bottom surface of the substrate, followed by a wet etch of the bottom surface to expose the heavily doped p+ layer. A metal contact is then formed over the p+ layer. In another improvement, edge termination structures utilize p-dopants implanted in trenches to create deep p-regions for shaping the electric field, and shallow p-regions between the trenches for rapidly removing holes after turn-off. In another improvement, a dual buffer layer using an n-layer and distributed n+ regions improves breakdown voltage and saturation voltage. In another improvement, p-zones of different concentrations in a termination structure are formed by varying pitches of trenches. In another improvement, beveled saw streets increase breakdown voltage.

In one embodiment, a power MOSFET cell includes an N+ silicon substrate having a drain electrode. An N-type drift layer is grown over the substrate. An N-type layer, having a higher dopant concentration than the drift region, is then formed along with a trench having sidewalls. A P-well is formed in the N-type layer, and an N+ source region is formed in the P-well. A gate is formed over the P-well's lateral channel and has a vertical extension into the trench. A positive gate voltage inverts the lateral channel and increases the vertical conduction along the sidewalls to reduce on-resistance. A vertical shield field plate is also located next to the sidewalls and may be connected to the gate. The field plate laterally depletes the N-type layer when the device is off to increase the breakdown voltage. A buried layer and sinker enable the use of a topside drain electrode.

The semiconductor device of the present invention includes a first conductivity type semiconductor layer made of a wide bandgap semiconductor and a Schottky electrode formed to come into contact with a surface of the semiconductor layer, and has a threshold voltage V.sub.th of 0.3 V to 0.7 V and a leakage current J.sub.r of 110.sup.9 A/cm.sup.2 to 110.sup.4 A/cm.sup.2 in a rated voltage V.sub.R.