A semiconductor device has a first substrate and a first semiconductor layer having a first semiconductor material formed over the first substrate. A surface of the first semiconductor layer has a first element of the first semiconductor material. A first surface of a second semiconductor layer having the first semiconductor material is joined to the surface of the first semiconductor layer. The first surface of the second semiconductor layer has a second element of the first semiconductor material different from the first element. The first semiconductor material is silicon carbide or cubic silicon carbide. The first element is silicon or carbon, and the second element is carbon or silicon. The semiconductor device provides characteristics of radiation hardening. A third semiconductor layer is formed over a second surface of the second semiconductor layer opposite the first surface. An electrical component is formed over the second semiconductor layer.

There is disclosed a structure in a wide band gap material such as silicon carbide wherein there is a buried grid and shields covering at least one middle point between two adjacent parts of the buried grid, when viewed from above. Advantages of the invention include easy manufacture without extra lithographic steps compared with standard manufacturing process, an improved trade-off between the current conduction and voltage blocking characteristics of a JBSD comprising the structure.

An SiC semiconductor device includes an SiC semiconductor layer including an SiC monocrystal and having a first main surface as an element forming surface, a second main surface at a side opposite to the first main surface, and a plurality of side surfaces connecting the first main surface and the second main surface, and a plurality of modified lines formed one layer each at the respective side surfaces of the SiC semiconductor layer and each extending in a band shape along a tangential direction to the first main surface of the SiC semiconductor layer and modified to be of a property differing from the SiC monocrystal.

A semiconductor device includes a chip, an electrode that is formed on the chip, an inorganic insulating layer that covers the electrode and has a first opening exposing the electrode, an organic insulating layer that covers the inorganic insulating layer, has a second opening surrounding the first opening at an interval from the first opening, and exposes an inner peripheral edge of the inorganic insulating layer in a region between the first opening and the second opening, and an Ni plating layer that covers the electrode inside the first opening and covers the inner peripheral edge of the inorganic insulating layer inside the second opening.

An embodiment relates to a semiconductor component, comprising a semiconductor body of a first conductivity type comprising a voltage blocking layer and islands of a second conductivity type on a contact surface and optionally a metal layer on the voltage blocking layer, and a first conductivity type layer comprising the first conductivity type not in contact with a gate dielectric layer or a source layer that is interspersed between the islands of the second conductivity type.

Disclosed are an MPS diode device and a preparation method therefor. The MPS diode device comprises a plurality of cells arranged in parallel, wherein each cell comprises a cathode electrode, and a substrate, epitaxial layer, buffer layer, and anode electrode that are formed in succession on the cathode electrode; two active regions are formed on the side of the epitaxial layer away from the substrate; the width of forbidden band of the buffer layer is greater than the width of forbidden band of the epitaxial layer, and a material of the buffer layer and a material of the epitaxial layer are allotropes; and first openings are formed at the positions in the buffer layer opposite to the active regions, and an ohmic metal layer is formed in the first openings.

An electronic component includes a covered object, an electrode that covers the covered object and has an electrode side wall on the covered object, an inorganic insulating film that has an inner covering portion covering the electrode such as to expose the electrode side wall, and an organic insulating film that covers the electrode side wall.

An SiC semiconductor device includes an SiC semiconductor layer including an SiC monocrystal that is constituted of a hexagonal crystal and having a first main surface as a device surface facing a c-plane of the SiC monocrystal and has an off angle inclined with respect to the c-plane, a second main surface at a side opposite to the first main surface, and a side surface facing an a-plane of the SiC monocrystal and has an angle less than the off angle with respect to a normal to the first main surface when the normal is 0°.

A junction barrier Schottky diode device and a method for fabricating the same is disclosed. In the junction barrier Schottky device includes an N-type semiconductor layer, a plurality of first P-type doped areas, a plurality of second P-type doped areas, and a conductive metal layer. The first P-type doped areas and the second P-type doped are formed in the N-type semiconductor layer. The second P-type doped areas are self-alignedly formed above the first P-type doped areas. The spacing between every neighboring two of the second P-type doped areas is larger than the spacing between every neighboring two of the first P-type doped areas. The conductive metal layer, formed on the N-type semiconductor layer, covers the first P-type doped areas and the second P-type doped areas.

The present techniques relate to a semiconductor device having resistance which has a positive temperature coefficient and a suitable value, and to a method for manufacturing a semiconductor device having resistance which has a positive temperature coefficient and a suitable value. The semiconductor device related to the present techniques is a bipolar device in which a current flows through a pn junction. The semiconductor device includes an n-type silicon carbide drift layer, a p-type first silicon carbide layer formed on the silicon carbide drift layer, and a p-type second silicon carbide layer formed on the first silicon carbide layer. Then, the second silicon carbide layer has a positive temperature coefficient of resistance.