A cell structure of a silicon carbide MOSFET device, comprising a first conductivity type drift region (3) located above a first conductivity type substrate (2). A main trench is provided in the surface of the first conductivity type drift region (3); a Schottky metal (4) is provided on the bottom and sidewalls of the main trench; a second conductivity type well region (7) is provided in the surface of the first conductivity type drift region (3) and around the main trench; a source region (8) is provided in the surface of the well region (7); a source metal (10) is provided above the source region (8); a gate insulating layer (6) and a gate (5) split into two parts are provided above the sides of the source region (8), the well region (7), and the first conductivity type drift region (3) close to the main trench.

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.

Provided is a semiconductor device whose performance is improved. A p type body region is formed in an n type semiconductor layer containing silicon carbide, and a gate electrode is formed on the body region with a gate insulating film interposed therebetween. An n type source region is formed in the body region on a side surface side of the gate electrode, and the body region and a source region are electrically connected to a source electrode. A p type field relaxation layer FRL is formed in the semiconductor layer on the side surface side of the gate electrode, and the source electrode is electrically connected to the field relaxation layer FRL. The field relaxation layer FRL constitutes a part of the JFET 2Q which is a rectifying element, and a depth of the field relaxation layer FRL is shallower than a depth of the body region.

An SBD of a JBS structure has on a front side of a semiconductor substrate, nickel silicide films in ohmic contact with p-type regions and a FLR, and a titanium film forming a Schottky junction with an n.sup.−-type drift region. A thickness of each of the nickel silicide films is in a range from 300 nm to 700 nm. The nickel silicide films each has a first portion protruding from the front surface of the semiconductor substrate in a direction away from the front surface of the semiconductor substrate, and a second portion protruding in the semiconductor substrate from the front surface of the semiconductor substrate in a depth direction. A thickness of the first portion is equal to a thickness of the second portion. A width of the second portion is wider than a width of the first portion.

The disclosure relates to a semiconductor die with a transistor device, having a source region, a drain region, a body region including a channel region, a gate region, which includes a gate electrode, next to the channel region, for controlling a channel formation, a drift region between the channel region and the drain region, and a field electrode region with a field electrode formed in a field electrode trench, which extends into the drift region, wherein the channel region extends laterally and is aligned vertically with the gate region, and wherein at least a portion of the channel region is arranged vertically above the field electrode region.

A semiconductor apparatus capable of reducing the leakage current in the reverse direction, and keeping characteristics thereof, even when using n type semiconductor (gallium oxide, for example) or the like having a low-loss at a high voltage and having much higher dielectric breakdown electric field strength than SiC is provided. A semiconductor apparatus includes a crystalline oxide semiconductor having a corundum structure as a main component, and an electric field shield layer and a gate electrode that are respectively laminated directly or through other layers on the n type semiconductor layer, wherein the electric field shield layer includes a p type oxide semiconductor, and is embedded in the n type semiconductor layer deeper than the gate electrode.

In SiC-MOSFETs including Schottky diodes, passage of a bipolar current to a second well region formed in a terminal portion sometimes reduces a breakdown voltage. In a SiC-MOSFET including Schottky diodes according to the present invention, the second well region formed in the terminal portion has a non-ohmic connection to a source electrode, and a field limiting layer lower in impurity concentration than the second well region is formed in a surface layer area of the second well region which is a region facing a gate electrode through a gate insulating film.

The present disclosure relates to: a MOSFET device which is applicable to a semiconductor device and, particularly, is manufactured using silicon carbide; and a manufacturing method therefor. The present disclosure provides a metal-oxide-semiconductor field effect transistor device which may comprise: a drain electrode; a substrate disposed on the drain electrode; an N-type drift layer disposed on the substrate; a plurality of P-type well layer regions disposed on the drift layer and spaced apart from each other to define a channel; an N+ region disposed on the well layer regions and adjacent to the channel; a P+ region disposed at the other side of the channel; a gate oxide layer disposed on the drift layer; a gate layer disposed on the gate oxide layer; and a source electrode disposed on the gate layer.

A power SiC MOSFET with a built-in Schottky rectifier provides advantages of including a Schottky rectifier, such as avoiding bipolar degradation, while reducing a parasitic capacitive charge and related power losses, as well as system cost. A lateral built-in channel layer may enable lateral spacing of the MOSFET gate oxide from a high electric field at the Schottky contact, while also providing current limiting during short-circuit events.

In an example, a semiconductor device includes an insulated gate transistor cell, a first region (e.g., a drain region and/or a drift region), a cathode region, a second region (e.g., an anode region and/or a separation region), and a source electrode. The insulated gate transistor cell includes a source region and a gate electrode. The source region and the cathode region are in a silicon carbide body. The gate electrode and the cathode region are electrically connected. The cathode region, the source region, and the first region have a first conductivity type. The second region has a second conductivity type and is between the cathode region and the first region. The source electrode and the source region are electrically connected. The source electrode and the second region are in contact with each other. A rectifying junction is electrically coupled between the source electrode and the cathode region.