An insulated gate silicon carbide semiconductor device includes: a drift layer of a first conductivity type on a silicon carbide substrate of 4H type with a {0001} plane having an off-angle of more than 0 as a main surface; a first base region; a source region; a trench; a gate insulating film; a protective diffusion layer; and a second base region. The trench sidewall surface in contact with the second base region is a surface having a trench off-angle of more than 0 in a <0001> direction with respect to a plane parallel to the <0001> direction. The insulated gate silicon carbide semiconductor device can relieve an electric field of a gate insulating film and suppress an increase in on-resistance and provide a method for manufacturing the same.

A silicon carbide semiconductor device includes a silicon carbide layer having a first main surface and a second main surface opposite to the first main surface. In the second main surface of the silicon carbide layer, a trench having a depth in a direction from the second main surface toward the first main surface is provided, and the trench has a sidewall portion where a second layer and a third layer are exposed and a bottom portion, where a first layer is exposed. A position of the bottom portion of the trench in a direction of depth of the trench is located on a side of the second main surface relative to a site located closest to the first main surface in a region where the second layer and the first layer are in contact with each other, or located as deep as the site in the direction of depth.

III-nitride materials are generally described herein, including material structures comprising III-nitride material regions and silicon-containing substrates. Certain embodiments are related to gallium nitride materials and material structures comprising gallium nitride material regions and silicon-containing substrates.

A method for fabricating a trench Schottky rectifier device is provided. At first, a plurality of trenched are formed in a substrate of a first conductivity type. An insulating layer is formed on sidewalls of the trenches. Then, an ion implantation procedure is performed through the trenches to form a plurality of doped regions of a second conductivity type under the trenches. Subsequently, the trenches are filled with conductive structure such as metal structure or tungsten structure. At last, an electrode overlying the conductive structure and the substrate is formed. Thus, a Schottky contact appears between the electrode and the substrate. Each doped region and the substrate will form a PN junction to pinch off current flowing toward the Schottky contact to suppress the current leakage in a reverse bias mode.

A lateral bipolar junction transistor (LBJT) device that may include a dielectric stack including a pedestal of a base region passivating dielectric and a nucleation dielectric layer; and a base region composed of a germanium containing material or a type III-V semiconductor material in contact with the pedestal of the base region passivating dielectric. An emitter region and collector region may be present on opposing sides of the base region contacting a sidewall of the pedestal of the base region passivating dielectric and an upper surface of the nucleation dielectric layer.

A lateral bipolar junction transistor (LBJT) device that may include a dielectric stack including a pedestal of a base region passivating dielectric and a nucleation dielectric layer; and a base region composed of a germanium containing material or a type III-V semiconductor material in contact with the pedestal of the base region passivating dielectric. An emitter region and collector region may be present on opposing sides of the base region contacting a sidewall of the pedestal of the base region passivating dielectric and an upper surface of the nucleation dielectric layer.

This invention discloses a semiconductor power device disposed in a semiconductor substrate comprising a lightly doped layer formed on a heavily doped layer and having an active cell area and an edge termination area. The edge termination area comprises a plurality P-channel MOSFETs. By connecting the gate to the drain electrode, the P-channel MOSFET transistors formed on the edge termination are sequentially turned on when the applied voltage is equal to or greater than the threshold voltage Vt of the P-channel MOSFET transistors, thereby optimizing the voltage blocked by each region.

A MOS gate structure is provided on a p-type base layer side of a silicon carbide semiconductor base formed by sequentially forming on a front surface of an n.sup.+-type silicon carbide substrate, an n-type drift layer and a p-type base layer by epitaxial growth. On the base front surface, in an edge termination structure region, a step portion occurring between the p-type base layer and the n-type drift layer, and a flat portion farther outward than the step portion are provided. In a surface layer of the n-type drift layer, a p.sup.+-type base region constituting the MOS gate structure is provided so as to contact the p-type base layer. The outermost p.sup.+-type base region extends from an active region into the flat portion and the entire lower side of this portion is covered by an innermost p.sup.-type region constituting an edge termination structure provided in the flat portion.

A semiconductor device with a deep trench has a dielectric liner formed on sidewalls and a bottom of the deep trench. A pre-etch deposition step of a two-step process forms a protective polymer on an existing top surface of the semiconductor device, and on the dielectric liner proximate to a top surface of the substrate. The pre-etch deposition step does not remove a significant amount of the dielectric liner from the bottom of the deep trench. A main etch step of the two-step process removes the dielectric liner at the bottom of the deep trench while maintaining the protective polymer at the top of the deep trench. The protective polymer is subsequently removed.

A semiconductor device includes a drift region extending from a first surface into a semiconductor portion. A body region between two portions of the drift region forms a first pn junction with the drift region. A source region forms a second pn junction with the body region. The pn junctions include sections perpendicular to the first surface. Gate structures extend into the body regions and include a gate electrode. Field plate structures extend into the drift region and include a field electrode separated from the gate electrode. A gate shielding structure is configured to reduce a capacitive coupling between the gate structures and a backplate electrode directly adjoining a second surface.