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.

A semiconductor device includes: a semiconductor substrate, a gate oxide layer, and a polysilicon field plate. The semiconductor substrate includes a drift region and a well region. An end of the drift region is arranged with a drain region, and an end of the well region is arranged with a source region. The gate oxide layer is arranged on the semiconductor substrate and disposed between the source region and the drain region. The polysilicon field plate is arranged on the gate oxide layer. At least a portion of the polysilicon field plate is projected onto the drift region and includes at least two field-plate regions. While the semiconductor device is operating, in a direction from an end of the drift region near the well region approaching the drain region, an equivalent electrical thickness of an insulating layer between the polysilicon field plate and the drift region gradually increases.

Disclosed is a trench-type power device and a manufacturing method thereof. The trench-type power device comprises: a semiconductor substrate; a drift region located on the semiconductor substrate; a first trench and a second trench located in the drift region; a gate stack located in the first trench; and Schottky metal located on a side wall of the second trench, wherein the Schottky metal and the drift region form a Schottky barrier diode. The trench-type power device adopts a double-trench structure, which combines a trench-type MOSFET with the Schottky barrier diode and forms the Schottky metal on the side wall of the trench, so that the performance of the power device can be improved, and the unit area of the power device can be reduced.

A method of fabricating a laterally diffused metal oxide semiconductor transistor including providing a substrate, forming a first well of a first doping polarity type in the substrate, forming a gate on a portion of the first well, the gate including an oxide layer and an at least partially conductive layer on the oxide layer, and forming a mask on at least a portion of the gate and at least a portion of the first well, wherein the mask has a sloping edge. The method further includes forming a second well of a second doping polarity type at least partially in the first well by implanting ions in the first well, the second well extending under a portion of the gate, the second doping polarity type being of opposite type to the first doping polarity type. The method includes forming a first one of a source and drain of the first doping polarity type in or on the second well, thereby defining a channel of the transistor under the gate. The method further includes forming a second one of the source and drain of the first doping polarity type in or on the first well, wherein the implanting includes directing at least a first beam of ions towards the first well at an angle substantially perpendicular to a surface plane of the substrate, and directing at least a second beam of ions towards the first well at an angle substantially offset from a surface normal of the substrate.

A semiconductor device includes a source region and a drain region of a first conductivity type, a body region of a second conductivity type between the source region and the drain region, a gate configured to control current through a channel of the body region, a drift zone of the first conductivity type between the body region and the drain region, a superjunction structure formed by a plurality of regions of the second conductivity type laterally spaced apart from one another by intervening regions of the drift zone, and a diffusion barrier structure disposed along sidewalls of the regions of the second conductivity type of the superjunction structure. The diffusion barrier structure includes alternating layers of Si and oxygen-doped Si and a Si capping layer on the alternating layers of Si and oxygen-doped Si.

A semiconductor device includes: an n.sup.−-type epitaxial layer having an element main surface; a p.sup.−-type body region, an n.sup.+-type source region, and n.sup.+-type drain regions; and a gate electrode including a second opening and first openings formed in a portion separated from the second opening toward the drain regions, wherein the body region selectively has a second portion exposed to the first openings of the gate electrode, and wherein the semiconductor device further includes a p.sup.+-type body contact region formed in the portion of the body region exposed to the first openings and having an impurity concentration higher than an impurity concentration of the body region.

According to an embodiment, provided is a semiconductor device including: a first electrode; a second electrode; and a silicon carbide layer disposed between the first electrode and the second electrode, the silicon carbide layer including: a first silicon carbide region of an n-type; and a second silicon carbide region disposed between the first silicon carbide region and the first electrode, the second silicon carbide being in contact with the first electrode, and the second silicon carbide containing one oxygen atom bonding with four silicon atoms.

A semiconductor device includes an electrical device and has an output capacitance characteristic with at least one output capacitance maximum located at a voltage larger than 5% of a breakdown voltage of the semiconductor device. The output capacitance maximum is larger than 1.2 times an output capacitance at an output capacitance minimum located at a voltage between the voltage at the output capacitance maximum and 5% of a breakdown voltage of the semiconductor device.

A power semiconductor device includes, an active area that conducts load current between first and second load terminal structures, a drift region, and a backside region that includes, inside the active area, first and second backside emitter zones one or both of which includes: first sectors having at least one first region of a second conductivity type contacting the second load terminal structure and a smallest lateral extension of at most 50 μm; and/or second sectors having a second region of the second conductivity type contacting the second load terminal structure and a smallest lateral extension of at least 50 μm. The emitter zones differ by at least of: the presence of first and/or second sectors; smallest lateral extension of first and/or second sectors; lateral distance between neighboring first and/or second sectors; smallest lateral extension of the first regions; lateral distance between neighboring first regions within the same first sector.

A semiconductor device (300) comprising: a doped semiconductor substrate (302); an epitaxial layer (304), disposed on top of the substrate, the epitaxial layer having a lower concentration of dopant than the substrate; a switching region disposed on top of the epitaxial layer; and a contact diffusion (350) disposed on top of the epitaxial layer, the contact diffusion having a higher concentration of dopant than the epitaxial layer; wherein the epitaxial layer forms a barrier between the contact diffusion and the substrate.