A semiconductor device contains a vertical MOS transistor having a trench gate in trenches extending through a vertical drift region to a drain region. The trenches have field plates under the gate; the field plates are adjacent to the drift region and have a plurality of segments. A dielectric liner in the trenches separating the field plates from the drift region has a thickness great than a gate dielectric layer between the gate and the body. The dielectric liner is thicker on a lower segment of the field plate, at a bottom of the trenches, than an upper segment, immediately under the gate. The trench gate may be electrically isolated from the field plates, or may be connected to the upper segment. The segments of the field plates may be electrically isolated from each other or may be connected to each other in the trenches.

In one general aspect, an apparatus can include a silicon carbide (SiC) device can include a gate dielectric, a first doped region having a first conductivity type, a source, a body region of the first conductivity type, and a second doped region having a second conductivity type. The second doped region can have a first portion and a second portion. The first portion can be disposed between the first doped region and the body region and the second portion can be disposed between the first doped region and the gate dielectric. The first portion of the second doped region can have a width less than a width of the first doped region.

A method for forming a power semiconductor device is provided. The method includes providing a substrate having a first surface and a second surface; and forming a plurality of trenches in the second surface of the substrate. The method also includes forming a semiconductor pillar in each of the plurality of trenches, wherein the semiconductor pillars and the substrate form a plurality of super junctions of the power semiconductor device for increasing the breakdown voltage of the power semiconductor device and reducing the on-stage voltage of the power semiconductor device; and forming a gate structure on the first surface of the substrate. Further, the method includes forming a plurality of well regions in the first surface of the substrate around the gate structure; and forming a source region in each of the plurality of well regions around the gate structure.

A structure having high, middle, and low impurity concentration regions disposed from a surface side of a substrate is more suitably manufactured. A method of manufacturing a semiconductor device includes: a first implantation of first conductivity type impurities into a first conductivity type semiconductor substrate from a surface; melting and solidifying a first semiconductor region between a depth and the surface, wherein the depth is deeper than a depth having a peak impurity concentration in an increased region where the impurity concentration was increased in the first implantation, and shallower than a deeper end of the increased region; a second implantation of the impurities from the surface into a region shallower than the depth; and melting and solidifying a region in which the impurity concentration was increased in the second implantation.

According to one embodiment, a semiconductor device is provided. The semiconductor device has a first region formed of semiconductor and a second region formed of semiconductor which borders the first region. An electrode is formed to be in ohmic-connection with the first region. A third region is formed to sandwich the first region. A first potential difference is produced between the first and the second regions in a thermal equilibrium state, according to a second potential difference between the third region and the first region.

A vertical conduction integrated electronic device including: a semiconductor body; a trench that extends through part of the semiconductor body and delimits a portion of the semiconductor body, which forms a first conduction region having a first type of conductivity and a body region having a second type of conductivity, which overlies the first conduction region; a gate region of conductive material, which extends within the trench; an insulation region of dielectric material, which extends within the trench and is arranged between the gate region and the body region; and a second conduction region, which overlies the body region. The second conduction region is formed by a conductor.

A switched-mode power converter includes an inductive storage element and a cascode circuit. The cascode circuit includes a double-gate field effect transistor. A switchable load path of the double-gate field effect transistor is electrically connected in series with the inductive storage element.

An interface device includes an NPN structure along a horizontal surface of a p-doped substrate. The NPN structure has a first n-doped region coupled to an output terminal, a p-doped region surrounding the first n-doped region and coupled to the output terminal, and a second n-doped region separated from the first n-doped region by the p-doped region. The interface device also includes a PNP structure along a vertical depth of the p-doped substrate. The PNP structure includes the p-doped region, an n-doped layer under the p-doped region, and the p-doped substrate. Advantageously, the interface device can withstand high voltage swing (both positive and negative), prevent sinking and sourcing large load current, and avoid entering into a low resistance mode during power down operations.

A method for manufacturing a semiconductor device is provided. The method includes operations below. First, an epitaxial layer is formed on a substrate. Then, a trench is formed in the epitaxial layer. Then, a first dielectric layer and a shield layer are formed in the trench, in which the shield layer is embedded within the first dielectric layer. Then, a spacer layer is formed in the trench and on the first dielectric layer. Finally, a second dielectric layer and a gate are formed in the trench and on the spacer layer, and a source is formed in the epitaxial layer surrounding the trench, in which the gate is embedded within the second dielectric layer, and the source surrounds the gate.

In one embodiment, a semiconductor device comprises a bulk semiconductor substrate that includes a first conductivity type floating buried doped region bounded above by a second conductivity type doped region and bounded below by another second conductivity semiconductor region. Dielectric isolation regions extend through the second conductivity doped region and the first conductivity floating buried doped region into the semiconductor region. Functional devices are disposed within the second conductivity type doped region. The first conductivity type floating buried doped region is configured as a self-biased region that laterally extends between adjacent dielectric isolation regions.