A crystalline oxide film with excellent crystalline qualities that is useful for semiconductors requiring heat dissipation is provided. A crystalline oxide film including a first crystal axis, a second crystal axis; a metal oxide as a major component that includes gallium, a first side; and a second side that is shorter than the first side, a linear thermal expansion coefficient of the first crystal axis is smaller than a linear thermal expansion coefficient of the second crystal axis, a direction of the first side is parallel and/or substantially parallel to a direction of the first crystal axis, and a direction of the second side is parallel and/or substantially parallel to a direction of the second crystal axis.

A method for forming a semiconductor device includes: forming, in a silicon carbide layer of a first conductivity type having a first side, a first silicon carbide region and a second silicon carbide region that forms a pn-junction with the first silicon carbide region; forming a contact region that forms an Ohmic contact with the second silicon carbide region; forming a barrier-layer on the contact region and the first silicon carbide region so that a Schottky-junction is formed between the barrier-layer and the first silicon carbide region and so that an Ohmic connection is formed between the barrier-layer and the contact region, the barrier-layer comprising molybdenum nitride; and forming a first metallization on the barrier-layer, and in Ohmic connection with the barrier-layer.

This invention discloses a semiconductor power device disposed in a semiconductor substrate and the semiconductor substrate has a plurality of trenches. Each of the trenches is filled with a plurality of epitaxial layers of alternating conductivity types constituting nano tubes functioning as conducting channels stacked as layers extending along a sidewall direction with a Gap Filler layer filling a merging-gap between the nano tubes disposed substantially at a center of each of the trenches. The Gap Filler layer can be very lightly doped Silicon or grown and deposited dielectric layer. In an exemplary embodiment, the plurality of trenches are separated by pillar columns each having a width approximately half to one-third of a width of the trenches.

A semiconductor device includes an upper and lower mirror. At least one active region for light generation is between the upper and lower mirror. At least one cavity spacer layer is between at least one of the upper and lower mirror and the active region. The device includes an inner mode confinement region and an outer current blocking region. A depleted heterojunction current blocking region (DHCBR) including a depleting impurity is within the outer current blocking region of 1 of the upper mirror, lower mirror, and the first active region. A middle layer including a conducting channel is within the inner mode confinement region that is framed by the DHCBR. The DHCBR forces current flow into the conducting channel during normal operation of the light source.

A semiconductor device of an embodiment includes a transistor device in a semiconductor die including a semiconductor body. The transistor device includes transistor cells connected in parallel and covering at least 80% of an overall active area at a first surface of the semiconductor body. The semiconductor device further includes a control terminal contact area at the first surface electrically connected to a control electrode of each of the transistor cells. A first load terminal contact area at the first surface electrically connected to a first load terminal region of each of the transistor cells. The semiconductor device further includes a resistor in the semiconductor die and electrically coupled between the control terminal contact area and the first load terminal contact area, and a pn junction diode electrically connected in series with the resistor.

A semiconductor film, a sheet like object, and a semiconductor device are provided that have inhibited semiconductor properties, particularly leakage current, and excellent withstand voltage and heat dissipation. A crystalline semiconductor film or a sheet like object includes a corundum structured oxide semiconductor as a major component, wherein the film has a film thickness of 1 m or more. Particularly, the semiconductor film or the object includes a semiconductor component of oxide of one or more selected from gallium, indium, and aluminum as a major component. A semiconductor device has a semiconductor structure including the semiconductor film or the object.

A high power semiconductor device with a floating field ring termination includes a wafer, wherein a plurality of floating field rings is formed in an edge termination region adjacent to a first main side surface of the wafer. At least in the termination region a drift layer, in which the floating field rings are formed, includes a surface layer and a bulk layer wherein the surface layer is formed adjacent to the first main side surface to separate the bulk layer from the first main side surface and has an average doping concentration which is less than 50% of the minimum doping concentration of the bulk layer. The drift layer includes a plurality of enhanced doping regions, wherein each one of the enhanced doping regions is in direct contact with a corresponding one of the floating field rings at least on a lateral side of this floating field ring, which faces towards the active region. The relatively low doped surface layer and the enhanced doping regions increase the electric field coupling from floating field ring to floating field ring, thus allowing an area efficient termination structure. Each enhanced doping region extends to at least the same depth as the one of the corresponding floating field ring.

A vertical JFET is provided. The JFET is mixed with lateral channel structure and p-GaN gate structure. The JFET has an improved barrier layer for p-GaN block layer and enhanced Ohmic contact with source. In one embodiment, regrowth of lateral channel is provided so that counter doping surface Mg will be buried. In another embodiment, a dielectric layer is provided to protect p-type block layer during the processing, and later make Ohmic source and p-type block layer. Method of a barrier regrown layer for enhanced lateral channel performance is provided where a regrown barrier layer is deposited over the drift layer. The barrier regrown layer is an anti-p-doping layer. Method of a patterned regrowth for enhanced Ohmic contact is provided where a patterned masked is used for the regrowth.

A high voltage device includes: a semiconductor layer, a well, a body region, a gate, a source, a drain, a drift oxide region, and a top region. The well is formed in the semicoducotor layer. The body region is formed in the well. The gate is formed on the well. The source and the drain are located below, outside, and at different sides of the gate, in the body region and the well respectively. The drift oxide region is formed on a drift region, wherein a bottom surface of the drift oxide region is higher than a first trench bottom surface of the first trench. The top region is formed in the well right below the drift oxide region, and is in contact with the drift oxide region.

Techniques for integrating a self-aligned heterojunction for TFETs in a vertical GAA architecture are provided. In one aspect, a method of forming a vertical TFET device includes: forming a doped SiGe layer on a Si substrate; forming fins that extend through the doped SiGe layer and partway into the Si substrate such that each of the fins includes a doped SiGe portion disposed on a Si portion with a heterojunction therebetween, wherein the SiGe portion is a source and the Si portion is a channel; selectively forming oxide spacers, aligned with the heterojunction, along opposite sidewalls of only the doped SiGe portion; and forming a gate stack around the Si portion and doped SiGe that is self-aligned with the heterojunction. A vertical TFET device formed by the method is also provided.