The present invention addresses the problem of providing a novel SiC epitaxial substrate manufacturing method and manufacturing device therefor. An SiC substrate and an SiC material, which has a lower doping concentration than said SiC substrate, are heated facing one another, and material is transported from the SiC material to the SiC substrate to form an SiC epitaxial layer. As a result, in comparison with the existing method (chemical vapour deposition), it is possible to provide an SiC epitaxial substrate manufacturing method with a reduced number of parameters to be controlled.

Embodiments disclosed herein include transistor devices with depopulated channels. In an embodiment, the transistor device comprises a source region, a drain region, and a vertical stack of semiconductor channels between the source region and the drain region. In an embodiment, the vertical stack of semiconductor channels comprises first semiconductor channels, and a second semiconductor channel over the first semiconductor channels. In an embodiment, first concentrations of a dopant in the first semiconductor channels are less than a second concentration of the dopant in the second semiconductor channel.

In some implementations, a method may include forming a multi-layer stack over a substrate. The multi-layer stack has alternating layers of first semiconductor layers and second semiconductor layers. Additionally, the device may include removing the first semiconductor layers in a first region of the substrate. The device may also include forming a disposable material between the second semiconductor layers in the first region. Moreover, the device may include forming source/drain regions adjacent to the second semiconductor layers and the disposable material in the first region. Finally, the device may include replacing the disposable material in the first region with metal gate structures.

The present application discloses a method for making an integrated structure of an MOS transistor having different operation voltages. The resulting integrated structure of an MOS transistor employs a hybrid gate solution. A resulting low voltage MOS transistor adopts a high-K metal gate, so that the gate leakage of the LV (low voltage) MOS transistor can be reduced and speed performance is maintained; and a resulting medium voltage MOS transistor and a high voltage MOS transistor adopt a poly gate, the gate oxide is a single oxide, and a high-K film (HK film) is not present, so that the resulting medium voltage MOS transistor and high voltage MOS transistor are highly reliable without any other reliability problems due to the introduction of a high-K film (HK film) and a gate metal film.

In a method of manufacturing a semiconductor device, a first-conductivity type implantation region is formed in a semiconductor substrate, and a carbon implantation region is formed at a side boundary region of the first-conductivity type implantation region.

An integrated circuit includes a dielectric isolation structure formed at a surface of a semiconductor substrate and a polysilicon resistor body formed on the dielectric isolation structure. The polysilicon resistor body includes an N-type dopant having an N-type dopant concentration, nitrogen having a nitrogen concentration, and carbon having a carbon concentration. The sheet resistance of the resistor body is greater than 5k/square.

The disclosure relates to a type trench gate silicon carbide MOSFET device and a fabrication method thereof. To protect a trench gate oxide layer without increasing a channel resistance and process complexity, a second conductivity type of heavily doped deep well inserted with double gate trenches along the sidewalls of deep well is designed. The deep well is connected to the source metal directly. The electric potential is clamped to the source during the voltage blocking and turn-off state, which reduces the electric field in the gate oxide and reduces the miller capacitance. An interlayer dielectric layer is deposited above the conductive dielectric polysilicon layers and extends outward separately to cover a part of the source region. A smaller cell pitch can be achieved by controlling the spacing between the first and the second trench gate, thereby increasing the channel density and reducing the channel resistance.

A silicon carbide semiconductor device includes a drift layer, a channel layer on the drift layer, the channel layer having a first conductivity type, a trench in the channel layer and a mesa adjacent to the trench, and a gate region within the trench. The gate region has a second conductivity type opposite the first conductivity type, and the gate region includes an epitaxially regrown layer. A method of forming a silicon carbide semiconductor device includes providing a drift layer, forming a channel layer on the drift layer, the channel layer having a first conductivity type, etching the channel layer to form a trench in the channel layer and a mesa adjacent to the trench, and epitaxially regrowing a gate region within the trench, wherein the gate region has a second conductivity type opposite the first conductivity type.

A semiconductor device includes a well formed in a semiconductor substrate, the well including a threshold voltage (Vt) implant. A source region and a drain region is created in the well, and a gate contact is formed over an oxide layer. The source region includes a source extension that is extended under a portion of the gate contact to create an integrated capacitor.

A semiconductor structure and method for manufacturing thereof are provided. The semiconductor structure includes a silicon substrate having a first surface, a III-V layer on the first surface of the silicon substrate and over a first active region, and an isolation region in a portion of the III-V layer extended beyond the first active region. The first active region is in proximal to the first surface. The method includes the following operations. A silicon substrate having a first device region and a second device region is provided, a first active region is defined in the first device region, a III-V layer is formed on the silicon substrate, an isolation region is defined across a material interface in the III-V layer by an implantation operation, and an interconnect penetrating through the isolation region is formed.