A semiconductor device and a manufacturing method thereof are provided. The gate structure and the source and drain terminals are located in the insulating dielectric layer, and the source and drain terminals are located respectively at both opposite ends of the gate structure. The channel region is sandwiched between the gate structure and the source and drain terminals and surrounds the gate structure. The channel region extends between the source and drain terminals.

A trench MOSFET with closed cell layout having shielded gate is disclosed, wherein closed gate trenches surrounding a deep trench in each unit cell and the shielded gate disposed in the deep trench. Trenched source-body contacts are formed between the closed gate trenches and the deep trench. The deep trench has square, rectangular, circle or hexagon shape.

Provided is a vertical MOSFET in which a conduction deterioration phenomenon is prevented during a current return operation and an on-voltage is low during the current return operation. A semiconductor device includes a hole barrier region that is provided between a second-conductivity-type body region and a first-conductivity-type epitaxial layer below a second-conductivity-type body contact region and functions as a potential barrier to a hole which flows from a source electrode to the first-conductivity-type epitaxial layer through the second-conductivity-type body contact region and the second-conductivity-type body region.

A high voltage metal-oxide-semiconductor laterally diffused device (HV LDMOS), and more particularly an insulated gate bipolar junction transistor (IGBT), is disclosed. The device includes a semiconductor substrate, a gate structure formed on the substrate, a source and a drain formed in the substrate on either side of the gate structure, a first doped well formed in the substrate, and a second doped well formed in the first well. The gate, source, second doped well, a portion of the first well, and a portion of the drain structure are surrounded by a deep trench isolation feature and an implanted oxygen layer in the silicon substrate.

A reverse-conducting MOS device is provided having an active cell region and a termination region. Between a first and second main side. The active cell region comprises a plurality of MOS cells with a base layer of a second conductivity type. On the first main side a bar of the second conductivity type, which has a higher maximum doping concentration than the base layer, is arranged between the active cell region and the termination region, wherein the bar is electrically connected to the first main electrode. On the first main side in the termination region a variable-lateral-doping layer of the second conductivity type is arranged. A protection layer of the second conductivity type is arranged in the variable-lateral-doping layer, which protection layer has a higher maximum doping concentration than the maximum doping concentration of the variable-lateral-doping layer in a region attached to the protection layer.

A method of forming a power semiconductor device includes: arranging a control electrode at least partially on or inside a semiconductor body; forming elevated source regions in the semiconductor body by: implanting first conductivity type dopants into the semiconductor body; forming a recess mask layer covering at least areas of intended source regions; and removing portions of the semiconductor body uncovered by the recess mask layer to form the elevated source regions and recessed body regions at least partially between the source regions. A dielectric layer is formed on the semiconductor body. A contact hole mask layer is formed on the dielectric layer. Portions of the dielectric layer uncovered by the contact hole mask layer are removed to form a contact hole which is filled at least partially with a conductive material to establish an electrical contact with at least a portion of the elevated source and recessed body regions.

A silicon carbide semiconductor device includes a silicon carbide layer and a gate insulating layer. The silicon carbide layer has a main surface. The gate insulating layer is arranged as being in contact with the main surface of the silicon carbide layer. The silicon carbide layer includes a drift region having a first conductivity type, a body region having a second conductivity type different from the first conductivity type and being in contact with the drift region, a source region having the first conductivity type and arranged as being spaced apart from the drift region by the body region, and a protruding region arranged to protrude from at least one side of the source region and the drift region into the body region, being in contact with the gate insulating layer, and having the first conductivity type.

A semiconductor device of according to an embodiment of the present disclosure includes a n-type SiC layer; a SiC region provided on the n-type SiC layer and containing H (hydrogen) or D (deuterium) in an amount of 1×10.sup.18 cm.sup.−3 or more and 1×10.sup.22 cm.sup.−3 or less; and a metal layer provided on the SiC region.

To improve the breakdown voltage of a semiconductor device. In a terminal region of the semiconductor device, a mesa groove, a recess groove, an electric field relaxation region, and a gradient distributed low concentration p-type layer region are formed. A recess groove is fromed between a device region and the mesa groove so as to surround the device region. A region where a p-type layer is thinned by the recess groove is the electric field relaxation region. The gradient distributed low concentration p-type layer region is formed on the surface of the electric field relaxation region. The average carrier concentration of the entire gradient distributed low concentration p-type layer region is lower than the carrier concentration of the p-type layer. By forming the gradient distributed low concentration p-type layer region, the electric field relaxation region is quickly completely depleted when a reverse voltage is applied, thereby improving the breakdown voltage.

A semiconductor power device may include a lightly doped layer formed on a heavily doped layer. One or more devices are formed in the lightly doped layer. Each device may include a body region, a source region, and one or more gate electrodes formed in corresponding trenches in the lightly doped region. Each of the trenches has a depth in a first dimension, a width in a second dimension and a length in a third dimension. The body region is of opposite conductivity type to the lightly and heavily doped layers. The source region is formed proximate the upper surface. One or more deep contacts are formed at one or more locations along the third dimension proximate one or more of the trenches. The contacts extend in the first direction from the upper surface into the lightly doped layer and are in electrical contact with the source region.