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 semiconductor device of embodiments includes: an element region including a transistor and a first diode; a termination region surrounding the element region and including a second diode; and an intermediate region between the element region and the termination region. The element region includes a first electrode, a second electrode, a gate electrode, a silicon carbide layer, and a gate insulating layer. The termination region includes a first wiring layer electrically connected to the first electrode, the second electrode, and the silicon carbide layer. The intermediate region includes a gate electrode pad, a first connection layer electrically connecting the first electrode and a part of the first wiring layer, a second connection layer electrically connecting the first electrode and another part of the first wiring layer, a second wiring layer electrically connected to the gate electrode pad and the gate electrode, and the silicon carbide layer.

A trench MOSFET device includes a semiconductor layer of a first doping type. MOS transistor cells are in a body region of a second doping type in the semiconductor layer. The transistor cells include a first cell type including a first trench providing a first gate electrode or the first gate electrode is on the semiconductor surface between the first trench and a second trench, and a first source region is formed in the body region. The first gate electrode is electrically isolated from the first source region. A second cell type has a third trench providing a second gate electrode or the second gate electrode is on the semiconductor surface between the third trench and a fourth trench, and a second source region is in the body region. An electrically conductive member directly connects the second gate electrode, first source region and second source region together.

A multi-cell MOSFET device including a MOSFET cell with an integrated Schottky diode is provided. The MOSFET includes n-type source regions formed in p-type well regions which are formed in an n-type drift layer. A p-type body contact region is formed on the periphery of the MOSFET. The source metallization of the device forms a Schottky contact with an n-type semiconductor region adjacent the p-type body contact region of the device. Vias can be formed through a dielectric material covering the source ohmic contacts and/or Schottky region of the device and the source metallization can be formed in the vias. The n-type semiconductor region forming the Schottky contact and/or the n-type source regions can be a single continuous region or a plurality of discontinuous regions alternating with discontinuous p-type body contact regions. The device can be a SiC device. Methods of making the device are also provided.

A device that increases a value of current flowing through a whole chip until a p-n diode in a unit cell close to a termination operates and reduces a size of the chip and a cost of the chip resulting from the reduced size. The device includes a second well region located to sandwich the entirety of a plurality of first well regions therein in plan view, a third separation region located to penetrate the second well region from a surface layer of the second well region in a depth direction, and a second Schottky electrode provided on the third separation region.

A semiconductor device includes first and second second-conductivity-type region groups containing multiple second-conductivity-type regions that are disposed on a first silicon carbide semiconductor layer of a first conductivity type, arrayed in parallel following one direction with a space between each other, and first and second electrodes disposed on the first silicon carbide semiconductor layer and forming a Schottky junction with the first silicon carbide semiconductor layer. The first electrode covers a position where a distance from adjacent first and second second-conductivity-type regions included in a first second-conductivity-type region group, and a distance from a third second-conductivity-type region included in a second second-conductivity-type region group and adjacent to the first and second second-conductivity-type regions, are equal. A Schottky barrier between the first electrode and the first silicon carbide semiconductor layer is larger than a Schottky barrier between the second electrode and the first silicon carbide semiconductor layer.

A plurality of gate trenches is formed into an epitaxial region of a first conductivity type over a semiconductor substrate. One or more contact trenches are formed into the epitaxial region, each between two adjacent gate trenches. One or more source regions of the first conductivity type are formed in a top portion of the epitaxial region between a contact trench and a gate trench. A barrier metal is formed inside each contact trench.

Each gate trench is substantially filled with a conductive material separated from trench walls by a layer of dielectric material to form a gate . A heavily doped well region of a conductivity opposite the first type is provided in the epitaxial region proximate a bottom portion of each of the contact trenches. A horizontal width of a gap between the well region and the gate trench is about 0.05 nm to 0.2 nm.

A semiconductor device includes: a semiconductor substrate including a trench provided in a surface of the semiconductor substrate; a trench electrode provided in the trench; an interlayer insulating film covering a surface of the trench electrode and protruding from the surface of the semiconductor substrate; a Schottky electrode provided on the surface of the semiconductor substrate, provided in a position separated from the interlayer insulating film, and being in Schottky contact with the semiconductor substrate; an embedded electrode provided in a concave portion between the interlayer insulating film and the Schottky electrode and made of a metal different from a metal of the Schottky electrode; and a surface electrode covering the interlayer insulating film, the embedded electrode, and the Schottky electrode.

A semiconductor device includes an element portion and a gate pad portion on the same wide gap semiconductor substrate. The element portion includes a first trench structure having a plurality of first protective trenches and first buried layers formed deeper than gate trenches. The gate pad portion includes a second trench structure having a plurality of second protective trenches and second buried layers. The second trench structure is either one of a structure where the second trench structure includes: a p-type second semiconductor region and a second buried layer made of a conductor or a structure where the second trench structure includes a second buried layer formed of a metal layer which forms a Schottky contact. The second buried layer is electrically connected with the source electrode layer.

A MOSFET device and fabrication method are disclosed. The MOSFET has a drain in chip plane with an epitaxial layer overlay atop. The MOSFET further comprises: a Kelvin-contact body and an embedded Kelvin-contact source; a trench gate extending into the epitaxial layer; a lower contact trench extending through the Kelvin-contact source and at least part of the Kelvin-contact body defining respectively a vertical source-contact surface and a vertical body-contact surface; a patterned dielectric layer atop the Kelvin-contact source and the trench gate; a patterned top metal layer. As a result: a planar ledge is formed atop the Kelvin-contact source; the MOSFET device exhibits a lowered body Kelvin contact impedance and, owing to the presence of the planar ledge, a source Kelvin contact impedance that is lower than an otherwise MOSFET device without the planar ledge; and an integral parallel Schottky diode is also formed.