An integrated circuit includes a MOSFET device and a monolithic diode device, wherein the monolithic diode device is electrically connected in parallel with a body diode of the MOSFET device. The monolithic diode device is configured so that a forward voltage drop Vf.sub.D2 of the monolithic diode device is less than a forward voltage drop Vf.sub.D1 of the body diode of the MOSFET device. The forward voltage drop Vf.sub.D2 is process tunable by controlling a gate oxide thickness, a channel length and body doping concentration level. The tunability of the forward voltage drop Vf.sub.D2 advantageously permits design of the integrated circuit to suit a wide range of applications according to requirements of switching speed and efficiency.

A semiconductor device containing a vertical power MOSFET with a planar gate and an integrated Schottky diode is formed by forming a source electrode on an extended drain of the vertical power MOSFET to form the Schottky diode and forming the source electrode on a source region of the vertical power MOSFET. The Schottky diode is connected through the source electrode to the source region. A drain electrode is formed at a bottom of a substrate of the semiconductor device. The Schottky diode is connected through the extended drain of the vertical power MOSFET to the drain electrode.

The fabrication method for a silicon carbide semiconductor device according to this disclosure includes a step of forming a dielectric film over part of a silicon carbide layer, a step of forming an ohmic electrode adjoining the dielectric film on the silicon carbide layer, a step of removing an oxidized layer on the ohmic electrode, a step of forming a mask with its opening on the side opposite to the side where the ohmic electrode is adjoining the dielectric film on the ohmic electrode having the oxidized layer removed and on the dielectric film, and a step of wet etching of a film to be etched with hydrofluoric acid with the mask formed. With the fabrication method for a silicon carbide semiconductor device described in this disclosure, it is possible to fabricate a silicon carbide semiconductor device with reduced failure.

A semiconductor device and a method of making thereof are disclosed. The device includes a substrate heavily doped with a first conductivity type and an epitaxial layer lightly doped with the first conductivity type formed on the substrate. A buffer layer between the substrate and the epitaxial layer is doped with the first conductivity type at a doping level between that of the substrate and that of the epitaxial layer. A cell includes a body region doped with the second conductivity formed in the epitaxial layer. The second conductivity type is opposite the first conductivity type. The cell includes a source region doped with the first conductivity type and formed in at least the body region. The device further includes a short region doped with the second conductivity type formed in the epitaxial layer separated from source region of the cell by the body region of the cell wherein the short region is conductively coupled with the source region.

A vertical semiconductor device includes one or more of a substrate, a buffer layer over the substrate, one or more drift layers over the buffer layer, and a spreading layer over the one or more drift layers.

A semiconductor device is provided. A semiconductor device includes: a first semiconductor layer having an N-type conductivity; and a second semiconductor layer that is formed on the first semiconductor layer, wherein an active region is defined in the first semiconductor layer and the second semiconductor layer, the active region includes a plurality of first P pillars and a plurality of first N pillars alternately arranged along a first direction, in the active region, an upper pillar region including an upper region of the plurality of first P pillars and an upper region of the plurality of first N pillars, a lower pillar region including a lower region of the plurality of first P pillars and a lower region of the plurality of first N pillars, and a middle pillar region formed between the upper pillar region and the lower pillar region are defined, the entire charge amount of the upper pillar region is greater than the entire charge amount of the lower pillar region, and a P-type charge amount is greater than an N-type charge amount in the upper pillar region, while the N-type charge amount is greater than the P-charge amount in the lower pillar region.

The present disclosure relates to a super-junction device and a manufacturing method thereof. In the manufacturing method, a first plurality of semiconductor pillars are formed in an epitaxial layer and a sacrificial stack is formed above the epitaxial layer. The sacrificial stack is used as a hard mask both for a body region and for a source region, and has a sidewall which controls a channel length of the super-junction device to reduce process fluctuation in different batches and improve reliability of the super-junction device.

A semiconductor device includes: a first electrode; a first semiconductor layer; a first insulating film extending downward from an upper surface of the first semiconductor layer, the first insulating film being columnar; a second electrode located in the first insulating film, the second electrode extending in a vertical direction, the second electrode being columnar; a second semiconductor layer partially provided in an upper layer portion of the first semiconductor layer, the second semiconductor layer being next to the first insulating film with the first semiconductor layer interposed; a third semiconductor layer partially provided in an upper layer portion of the second semiconductor layer; and a third electrode located higher than the upper surface of the first semiconductor layer, the third electrode overlapping a portion of the first insulating film, a portion of the first semiconductor layer, and a portion of the second semiconductor layer when viewed from above.

A precursor for a vertical semiconductor device is provided with a substrate, a drift region over the substrate, and an upper precursor region over the drift region. The top surface of the precursor is substantially planar, and the substrate and the drift region are doped with a first dopant of a first polarity. In a first embodiment, a series of implants with a second dopant is provided in the upper precursor region via the top surface to form each of at least two gate regions such that each implant of the series of implants is provided at a different depth below the top surface. In a second embodiment, a series of implants with the first dopant is provided in the upper precursor region via the top surface to form a channel region that has at least a portion between two gate regions.

A vertical-conduction MOSFET device, includes: a semiconductor body, having a front side and a back side and having a first conductivity; a trench-gate region; a body region, having the first conductivity; a source region, having a second conductivity; and a drain region, having the second conductivity. The source region, body region, and drain region are aligned with one another along a first direction and define a channel area, which, in a conduction state of the MOSFET device, hosts a conductive channel. The drain region borders on a portion of the semiconductor body having the first conductivity, thus forming a junction diode, which, in an inhibition state of the MOSFET device, is adapted to cause a leakage current to flow outside the channel area.