A semiconductor device includes a gate extraction portion extracted from a gate electrode and extending from an active region to an outer peripheral region so as to be disposed above an end portion of a field insulating film. The end portion of the gate field insulating film above which the gate extraction portion is disposed is inclined in such a manner that a thickness of the field insulating film increases in a direction from the active region toward the outer peripheral region.

A semiconductor device includes: a substrate (10); a semiconductor layer (20) disposed on a main surface of this substrate (10); and a first main electrode (30) and a second main electrode (40), which are disposed on the substrate (10) separately from each other with the semiconductor layer (20) sandwiched therebetween and are individually end portions of a current path of a main current flowing in an on-state. The semiconductor layer (20) includes: a first conductivity-type drift region (21) through which a main current flows; a second conductivity-type column region (22) that is disposed inside the drift region (21) and extends in parallel to a current path; and an electric field relaxation region (23) that is disposed in at least a part between the drift region (21) and the column region (22) and is either a low-concentration region in which an impurity concentration is lower than in the same conductivity-type adjacent region or a non-doped region.

A semiconductor device includes: a drift region of a first conductive type including a contact section and extension sections extending along the main surface of a substrate; column regions of a second conductive type which alternate with the extension sections in a perpendicular direction to the extension direction of the extension sections and each includes an end connecting to the contact section; a well region of a second conductive type which connects to the other end of each column region and tips of the extension sections; and electric field relaxing electrodes which are provided above at least some of residual pn junctions with an insulating film interposed therebetween. Herein, the residual pn junctions are pn junctions other than voltage holding pn junctions formed in interfaces between the extension sections and the column regions.

Methods may include providing a device structure having a shielding layer formed beneath each trench in a MOSFET to protect trench corner breakdown. The method may include providing a device structure comprising an epitaxial layer, a well over the epitaxial layer, and a source layer over the well, and providing a plurality of trenches through the device structure. The method may further include forming a shielding layer in the device structure by directing ions into the plurality of trenches.

There is provided a semiconductor device including: a semiconductor layer including a main surface; a plurality of trenches including a plurality of first trench portions and a plurality of second trench portions, respectively; an insulating layer formed in an inner wall of each of the second trench portions; a first electrode buried in each of the second trench portions with the insulating layer interposed between the first electrode and each of the second trench portions; a plurality of insulators buried in the first trench portions so as to cover the first electrode; a contact hole formed at a region between the plurality of first trench portions in the semiconductor layer so as to expose the plurality of insulators; and a second electrode buried in the contact hole.

A method of processing a power semiconductor device includes: providing a semiconductor body with a drift region of a first conductivity type; forming a plurality of trenches extending into the semiconductor body along a vertical direction and arranged adjacent to each other along a first lateral direction; providing a mask arrangement at the semiconductor body, the mask arrangement having a lateral structure according to which some of the trenches are exposed and at least one of the trenches is covered by the mask arrangement along the first lateral direction; forming, below bottoms of the exposed trenches, a plurality of doping regions of a second conductivity type complementary to the first conductivity type; removing the mask arrangement; and extending the plurality of doping regions in parallel to the first lateral direction such that the plurality of doping regions overlap and form a barrier region of the second conductivity type adjacent to the bottoms of the exposed trenches.

An integrated circuit has a P-type substrate and an N-type LDMOS transistor. The LDMOS transistor includes a boron-doped diffused well (DWELL-B) and an arsenic-doped diffused well (DWELL-As) located within the DWELL-B. A first polysilicon gate having first sidewall spacers and a second polysilicon gate having second sidewall spacers are located over opposite edges of the DWELL-B. A source/IBG region includes a first source region adjacent the first polysilicon gate, a second source region adjacent the second polysilicon gate, and an integrated back-gate (IBG) region located between the first and second source regions. The first source region and the second source region each include a lighter-doped source sub-region, the IBG region including an IBG sub-region having P-type dopants, and the source/IBG region includes a heavier-doped source sub-region.

A semiconductor device includes a semiconductor part having a first surface and a second surface opposite to the first surface, a first electrode on the first surface, a second electrode on the second surface, first to third control electrodes between the first electrode and the semiconductor part. The first to third control electrodes are biased independently from each other. The semiconductor part includes a first layer of a first-conductivity-type, a second layer of a second-conductivity-type, a third layer of the first-conductivity-type and the fourth layer of the second-conductivity-type. The second layer is provided between the first layer and the first electrode. The third layer is selectively provided between the second layer and the first electrode. The fourth layer is provided between the first layer and the second electrode. The second layer opposes the first to third control electrode with insulating films interposed.

A semiconductor device, including a substrate, a deposition layer deposited on the substrate, a semiconductor region selectively provided in the deposition layer, a semiconductor layer provided on the deposition layer and the semiconductor region, a first region and a second region selectively provided in the semiconductor layer, a gate electrode provided on the second region and the semiconductor layer via a gate insulating film, a source electrode in contact with the semiconductor layer and the second region, an interlayer insulating film covering the gate electrode, a drain electrode provided on the substrate, a plating film selectively provided on the source electrode at portions thereof on which the protective film is not provided, and a pin-shaped electrode connected to the plating film via solder. The second region is not formed directly beneath a portion where the plating film, the protective film and the source electrode are in contact with one another.

Lateral double-diffused MOSFET transistor and fabrication method thereof are provided. A shallow trench isolation structure is formed in a semiconductor substrate. A drift region is formed in the semiconductor substrate and surrounding the shallow trench isolation structure. A body region is formed in the semiconductor substrate and distanced from the drift region. A gate structure is formed on a portion of each of the body region, the drift region, and the shallow trench isolation structure. A drain region is formed in the drift region on one side of the gate structure. A source region is formed in the body region on an other side of the gate structure. A first shallow doped region is formed in the drain region and the drift region to surround the shallow trench isolation structure.