The present disclosure relates to a semiconductor device with a contact structure and a method for preparing the semiconductor device. The semiconductor device includes a source/drain structure disposed over a semiconductor substrate, and a dielectric layer disposed over the source/drain structure. The semiconductor device also includes a polysilicon stack disposed over the source/drain structure and surrounded by the dielectric layer. The polysilicon stack includes a first polysilicon layer and a second polysilicon layer disposed over the first polysilicon layer. The first polysilicon layer is undoped, and the second polysilicon layer is doped. The semiconductor device further includes a contact structure disposed directly over the polysilicon stack and surrounded by the dielectric layer.

A method and structure providing a high-voltage transistor (HVT) including a gate dielectric, where at least part of the gate dielectric is provided within a trench disposed within a substrate. In some aspects, a gate oxide thickness may be controlled by way of a trench depth. By providing the HVT with a gate dielectric formed within a trench, embodiments of the present disclosure provide for the top gate stack surface of the HVT and the top gate stack surface of a low-voltage transistor (LVT), formed on the same substrate, to be substantially co-planar with each other, while providing a thick gate oxide for the HVTs. Further, because the top gate stack surface of HVT and the top gate stack surface of the LVT are substantially co-planar with each other, over polishing of the HVT gate stack can be avoided.

A through electrode substrate includes a substrate provided with a through hole; a through electrode having a sidewall portion extending along a sidewall of the through hole, and a first portion positioned on a first surface of the substrate and connected to the sidewall portion; an inorganic film that at least partially covers the first portion of the through electrode from the first side and is provided with an opening positioned on the first portion; and a first wiring structure including at least a first wiring layer having an insulation layer that is positioned to the first side of the inorganic film and includes at least an organic layer provided with an opening communicating with the opening of the inorganic film, and an electroconductive layer connected to the first portion of the through electrode through the opening of the inorganic film and the opening of the insulation layer.

The present disclosure relates to a semiconductor device with a contact structure and a method for preparing the semiconductor device. The semiconductor device includes a source/drain structure disposed over a semiconductor substrate, and a dielectric layer disposed over the source/drain structure. The semiconductor device also includes a polysilicon stack disposed over the source/drain structure and surrounded by the dielectric layer. The polysilicon stack includes a first polysilicon layer and a second polysilicon layer disposed over the first polysilicon layer. The first polysilicon layer is undoped, and the second polysilicon layer is doped. The semiconductor device further includes a contact structure disposed directly over the polysilicon stack and surrounded by the dielectric layer.

A power SiC MOSFET with a built-in Schottky rectifier provides advantages of including a Schottky rectifier, such as avoiding bipolar degradation, while reducing a parasitic capacitive charge and related power losses, as well as system cost. A lateral built-in channel layer may enable lateral spacing of the MOSFET gate oxide from a high electric field at the Schottky contact, while also providing current limiting during short-circuit events.

The disclosure relates to a semiconductor component having an SiC semiconductor body and a first load terminal on a first surface of the SiC semiconductor body. A second load terminal is formed on a second surface of the SiC semiconductor body opposite the first surface. The semiconductor component has a drift zone of a first conductivity type in the SiC semiconductor body and a first semiconductor area of a second conductivity type which is electrically connected to the first load terminal. A pn junction between the drift zone and the first semiconductor area defines a voltage blocking strength of the semiconductor component.

An embodiment is a semiconductor device includes a silicon carbide layer having a first plane and a second plane facing the first plane; a gate electrode; an aluminum nitride layer located between the silicon carbide layer and the gate electrode, the aluminum nitride layer containing an aluminum nitride crystal; a first insulating layer located between the silicon carbide layer and the aluminum nitride layer; and a second insulating layer located between the aluminum nitride layer and the gate electrode and having a wider band gap than the aluminum nitride layer.

An antifuse OTP memory bit cell comprises a gate electrode, a gate dielectric and source/drain diffusions formed in an active area of a semiconductor substrate. The source/drain diffusions are connected under the gate electrode by lateral diffusion but they don't have to be. If connected, a rectifying contact is created in a programmed bit cell. If unconnected, a rectifying contact or a non-rectifying contact is created in a programmed bit cell. Whether connected or unconnected, the device operates as an OTP memory bit cell without an access transistor.

An antifuse OTP memory bit cell comprises a gate electrode, a gate dielectric and source/drain diffusions formed in an active area of a semiconductor substrate. The source/drain diffusions are connected under the gate electrode by lateral diffusion but they don't have to be. If connected, a rectifying contact is created in a programmed bit cell. If unconnected, a rectifying contact or a non-rectifying contact is created in a programmed bit cell. Whether connected or unconnected, the device operates as an OTP memory bit cell without an access transistor.

An electrical device in which an interface layer is disposed in between and in contact with a conductor and a semiconductor.