A semiconductor substrate, a semiconductor device, a method for manufacturing a semiconductor substrate, and a method for manufacturing a semiconductor device are provided. The semiconductor substrate has a thermal conduction layer, a SiC (silicon carbide) layer formed on one principal surface side of the thermal conduction layer, having a 3C crystal structure, a bonding layer formed between the thermal conduction layer and the SiC layer, and a nitride semiconductor layer formed on one principal surface of the SiC layer.

The present disclosure relates to a power semiconductor device (100) comprising a silicon carbide semiconductor. SiC. structure (110) comprising a SiC epilayer (112), at least one ohmic contact (120) formed on a first main surface (114) of the SiC structure (110), and at least Schottky barrier contact (130) formed on a second main surface (116) of the SiC structure (110). The at least one Schottky barrier contact (130) comprises a metal layer (136) and a carbon group interlayer (134) arranged between the metal layer (136) and the second main surface (116) of the SiC structure (110). 15 The present disclosure relates to a Schottky barrier diode (400). a vertical field effect transistor, such as a power MOSFET (500), and a method for manufacturing a power semiconductor device (100).

A molding is formed by laminating an aggregate of SiC and a paste containing Si and C powders on an epitaxial layer of SiC formed on a support substrate of SiC to form an intermediate sintered body in which polycrystalline SiC is produced from the Si and C powders by reaction sintering, free Si is carbonized to SiC to form a sintered body layer, and the support substrate is removed from the epitaxial layer to form a semiconductor substrate in which the epitaxial layer and the sintered body layer are laminated.

Horizontal Cavity Surface Emitting Lasers (HCSELs) with angled facets may be fabricated by a chemical or physical etching process, and the epitaxially grown semiconductor device layers may be transferred through a selective etch and release process from their original epitaxial substrate to a carrier wafer.

A power device includes a substrate, a drift layer disposed on the substrate, a terminal region and an active region disposed in the drift layer, an electrode layer disposed on the active region, a Schottky contact layer disposed between the electrode layer and the active region, a passivation layer disposed on the drift layer, and an isolation layer disposed between the passivation layer and the electrode layer so that the passivation layer and the electrode layer are at least partially separated from each other. The isolation layer, the electrode layer, and the passivation layer each respectively has a thermal expansion coefficient a, b, c, and a>b>c.

A crystal that is useful for semiconductor element and a semiconductor element that has enhanced electrical properties are provided. A crystal, including: a corundum structured crystalline oxide, the crystalline oxide including gallium and/or indium, and the crystalline oxide further including a metal of Group 4 of the periodic table. The crystal is used to make a semiconductor element, and the obtained semiconductor element is used to make a semiconductor device such as a power card. Also, the semiconductor element and the semiconductor device are used to make a semiconductor system.

A merged PiN Schottky (MPS) diode includes a substrate, a first epitaxial layer of a first conductivity type, doped regions of a second conductivity type, a second epitaxial layer of the first conductivity type, and a Schottky metal layer. The first epitaxial layer is disposed on the first surface of the substrate. The doped regions are disposed in a surface of the first epitaxial layer, wherein the doped regions consist of first portions and second portions, the first portions are electrically floating, and the second portions are electrically connected to a top metal. The second epitaxial layer is disposed on the surface of the first epitaxial layer, wherein trenches are formed in the second epitaxial layer to expose the second portions of the doped regions. The Schottky metal layer is conformally deposited on the second epitaxial layer and the exposed second portions of the doped regions.

A method for forming an ohmic contact on a semiconductor component, for example a high-power electrical diode, is provided. An example method includes depositing a first metal layer on a top surface of a semiconductor drift layer having an electrical contact point, the first metal layer highly reflective of a laser light. The method further includes depositing a second metal layer on portions of the first metal layer aligned with the electrical contact point, the second metal layer selected to absorb the laser light. The method further includes exposing the first and the second metal layers to the laser light in a laser annealing process, causing the second metal layer to substantially increase in temperature due to the laser light. The increase in temperature of the second metal layer causing the ohmic contact to form between the electrical contact point and the first metal layer.

An electronic device comprising: a semiconductor body of silicon carbide, SiC, having a first and a second face, opposite to one another along a first direction, which presents positive-charge carriers at said first face that form a positive interface charge; a first conduction terminal, which extends at the first face of the semiconductor body; a second conduction terminal, which extends on the second face of the semiconductor body; a channel region in the semiconductor body, configured to house, in use, a flow of electrons between the first conduction terminal and the second conduction terminal; and a trapping layer, of insulating material, which extends in electrical contact with the semiconductor body at said channel region and is designed so as to present electron-trapping states that generate a negative charge such as to balance, at least in part, said positive interface charge.

Disclosed herein is a junction barrier Schottky diode that includes a semiconductor substrate, a drift layer provided on the semiconductor substrate, an anode electrode contacting the drift layer, a cathode electrode contacting the semiconductor substrate, and a p-type semiconductor layer contacting both the anode electrode and the drift layer. The p-type semiconductor layer includes a first p-type semiconductor layer contacting the anode electrode and a second p-type semiconductor layer contacting the drift layer. The second p-type semiconductor layer is lower in valence band upper end level than the first p-type semiconductor layer.