A semiconductor device having a voltage resistant structure in a first aspect of the present invention is provided, comprising a semiconductor substrate, a semiconductor layer on the semiconductor substrate, a front surface electrode above the semiconductor layer, a rear surface electrode below the semiconductor substrate, an extension section provided to a side surface of the semiconductor substrate, and a resistance section electrically connected to the front surface electrode and the rear surface electrode. The extension section may have a lower permittivity than the semiconductor substrate. The resistance section may be provided to at least one of the upper surface and the side surface of the extension section.

An electronic device is provided. The electronic device includes a first substrate, a multilayer structure, and a passivation layer. The multilayer structure is disposed on the first substrate. The multilayer structure includes a first conductive layer and a second conductive layer disposed on the first conductive layer. The passivation layer is disposed on the second conductive layer. In addition, a thermal expansion coefficient of the second conductive layer is between a thermal expansion coefficient of the first conductive layer and a thermal expansion coefficient of the passivation layer.

A semiconductor structure is provided. The semiconductor structure includes an insulator layer, first and second field-effect transistor devices, an isolation field-effect transistor device, front-side gate and back-side gate contacts. Each of the first and second field-effect transistor devices and the isolation field-effect transistor device includes a fin structure and first and second epitaxial source/drain structures. The fin structure includes channel layers and a gate structure that is wrapped around the channel layers. The first and second epitaxial source/drain structures are connected to opposite sides of the channel layers. The isolation field-effect transistor device is kept in the off-state. The front-side gate contact is formed on the first field-effect transistor device and electrically connected to the gate structure of the first field-effect transistor device. The back-side gate contact is formed passing through the insulator layer and electrically connected to the gate structure of the isolation field-effect transistor device.

An electronic power device includes a substrate of silicon carbide (SiC) having a front surface and a rear surface which lie in a horizontal plane and are opposite to one another along a vertical axis. The substrate includes an active area, provided in which are a number of doped regions, and an edge area, which is not active, distinct from and surrounding the active area. A dielectric region is arranged above the front surface, in at least the edge area. A passivation layer is arranged above the front surface of the substrate, and is in contact with the dielectric region in the edge area. The passivation layer includes at least one anchorage region that extends through the thickness of the dielectric region at the edge area, such as to define a mechanical anchorage for the passivation layer.

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.

An electronic power device includes a substrate of silicon carbide (SiC) having a front surface and a rear surface which lie in a horizontal plane and are opposite to one another along a vertical axis. The substrate includes an active area, provided in which are a number of doped regions, and an edge area, which is not active, distinct from and surrounding the active area. A dielectric region is arranged above the front surface, in at least the edge area. A passivation layer is arranged above the front surface of the substrate, and is in contact with the dielectric region in the edge area. The passivation layer includes at least one anchorage region that extends through the thickness of the dielectric region at the edge area, such as to define a mechanical anchorage for the passivation layer.

A semiconductor device and a method of manufacturing a semiconductor device according to one or more embodiments are disclosed. An interface layer is formed by implanting ionized impurities into a first layer comprising single-crystalline silicon carbide (SiC). Surfaces of the interface layer and a second layer comprising polycrystalline silicon carbide (SiC) are activated. The activated surfaces of the interface layer and the second layer are contacted and bonded. A covering layer is formed to cover a top surface and sides of the first layer, sides of the interface layer, and sides of the second layer.

An antenna device is provided. The antenna device includes a first substrate, a multilayer electrode, a second substrate, and a liquid-crystal layer. The multilayer electrode is disposed on the first substrate, and the multilayer electrode includes a first conductive layer, a second conductive layer, and a third conductive layer. The second conductive layer is disposed on the first conductive layer. The third conductive layer is disposed on the second conductive layer. The liquid-crystal layer is disposed between the first substrate and the second substrate. In addition, the third conductive layer includes a first portion that extends beyond the second conductive layer.

A semiconductor device according to an embodiment includes: a silicon carbide layer; a silicon oxide layer; and a region disposed between the silicon carbide layer and the silicon oxide layer and having a nitrogen concentration equal to or more than 1 × 10.sup.21 cm.sup.-3. A nitrogen concentration distribution in the silicon carbide layer, the silicon oxide layer, and the region have a peak in the region, a nitrogen concentration at a first position 1 nm away from the peak to the side of the silicon oxide layer is equal to or less than 1 × 10.sup.18 cm.sup.-3 and a carbon concentration at the first position is equal to or less than 1 × 10.sup.18 cm.sup.-3, and a nitrogen concentration at a second position 1 nm away from the peak to the side of the silicon carbide layer is equal to or less than 1 × 10.sup.18 cm-.sup.3.

Disclosed are a low-temperature processing method for improving a 4H—SiC/SiO.sub.2 interface based on a supercritical oxynitride, and use thereof. The method includes: performing standard cleaning on a silicon carbide sample to be processed; performing dry-oxygen oxidation on the cleaned silicon carbide sample to grow an oxide layer; placing the silicon carbide sample having the oxide layer on a support in a steady-state supercritical chamber; controlling a pressure and injecting nitrogen-oxygen gas into the supercritical device; increasing a temperature in the supercritical device from 23° C. to 500° C.; maintaining the above supercritical state until the processing ends; reducing a temperature of a reactor to room temperature after reaction ends, reducing the pressure to an atmospheric pressure, and taking out the reactor. The present disclosure allows for effective and quick decrease in the 4H—SiC/SiO.sub.2 interface state density, and also a significant decrease in the processing temperature.