A SiC semiconductor device includes a main cell region and sense cell region being electrically isolated by an element isolation portion. The SiC semiconductor device includes a substrate, a first impurity region, a first current dispersion layer, first deep layers, a second current dispersion layer, a second deep layer, a base region, a trench gate structure, a second impurity region, first electrodes and a second electrode. The second impurity region, the first electrodes, and the second electrode are disposed at the main cell region and the sense cell region to form a vertical semiconductor element. The vertical semiconductor element allows a current flowing between the first electrode and the second electrode through a voltage applied to the gate electrode. The spacing interval between the deep layers at the element isolation portion is shorter than or equal to a spacing interval between the deep layers at the main cell region.

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.

A semiconductor device is provided, which includes a substrate, a first and second doped wells, a drain and source regions, a gate structure, a field plate and a booster plate. The first and second doped wells are arranged in the substrate. The drain region is arranged in the first doped well and the source region is arranged in the second doped well. The gate structure is arranged over the substrate and between the source and drain regions. The field plate is arranged over the first doped well and the booster plate arranged between the field plate and the first doped well.

[Object] To provide a semiconductor device capable of improving a discharge starting voltage when measuring electric characteristics, and widening a pad area of a surface electrode or increasing the number of semiconductor devices (number of chips) to be obtained from one wafer, and a method for manufacturing the same.

[Solution Means] A semiconductor device 1 includes an n-type SiC layer 2 having a first surface 2A, a second surface 2B, and end faces 2C, a p-type voltage relaxing layer 7 formed in the SiC layer 2 so as to be exposed to the end portion of the first surface 2A of the SiC layer 2, an insulating layer 8 formed on the SiC layer 2 so as to cover the voltage relaxing layer 7, and an anode electrode 9 that is connected to the first surface 2A of the SiC layer 2 through the insulating layer 8 and has a pad area 95 selectively exposed.

Disclosed is a cellular structure of a silicon carbide MOSFET device, and a silicon carbide MOSFET device. The cellular structure comprises: second conductive well regions located on two sides of the cellular structure and arranged within the surface of a drift layer, first conductive source regions located within the surfaces of the well regions, and a gate structure located at the center of the cellular structure and in contact with the source regions, the well regions, and the drift layer. The cellular structure further comprises a source metal layer located above the source regions and forming ohmic contact with the source regions; on two sides of the cellular structure, side trenches are formed downwardly on regions of the drift layer that are not covered by the well regions; Schottky metal layers forming Schottky contact with the drift layer below the side trenches are arranged in the side trenches.

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.

A silicon carbide semiconductor device includes: a body region of a second conductivity type provided on a drift layer of a first conductivity type; a source region of a first conductivity type provided on the body region; a source electrode connected to the source region; a gate insulating film provided on an inner surface of a trench; a gate electrode provided inside the trench with interposition of the gate insulating film; a protective layer of a second conductivity type provided below the gate insulating film; a connection layer of a second conductivity type being in contact with the protective layer and the body region; and an electric field relaxation layer of a second conductivity type being in contact with a bottom surface of the connection layer, provided below the connection layer, and having a lower impurity concentration of a second conductivity type than the connection layer.

A semiconductor device includes a transistor cell with a source region of a first conductivity type and a gate electrode. The source region is formed in a wide bandgap semiconductor portion. A diode chain includes a plurality of diode structures. The diode structures are formed in the wide bandgap semiconductor portion and electrically connected in series. Each diode structure includes a cathode region of the first conductivity type and an anode region of a complementary second conductivity type. A gate metallization is electrically connected with the gate electrode and with a first one of the anode regions in the diode chain. A source electrode structure is electrically connected with the source region and with a last one of the cathode regions in the diode chain.

A semiconductor device is described. The semiconductor device includes: a Si substrate having a first main surface; a plurality of gate trenches extending from the first main surface into the Si substrate; a semiconductor mesa between adjacent gate trenches; a first interlayer dielectric on the first main surface; a plurality of first metal contacts extending through the first interlayer dielectric and contacting gate electrodes disposed in the gate trenches; a plurality of second metal contacts extending through the first interlayer dielectric and contacting the semiconductor mesas; and an air gap or a dielectric material having a lower dielectric constant than the first interlayer dielectric between adjacent first and second metal contacts. Methods of producing the semiconductor device are also described.

A semiconductor device includes: a drift region of a first conductivity type arranged between first and second surfaces of a semiconductor body; a first region of the first conductivity type at the second surface; a second region of a second conductivity type arranged adjacent to the first region at the second surface, the second region including first and second sub-regions, the second sub-region arranged between the first sub-region and the second surface; and a first electrode on the second surface and arranged directly adjacent to the first region and the second sub-region. The first electrode is electrically connected to the drift region by the first region. The first sub-region protrudes, along a first lateral direction, over an interface or a separation region between the second sub-region and the first region. A part of the first region is confined by the first sub-region and the first electrode along a vertical direction.