One illustrative method disclosed herein includes forming a gate structure above a portion of a fin and performing a first epitaxial growth process to form a silicon-carbide (SiC) semiconductor material above the fin in the source and drain regions of a FinFET device. In this example, the method also includes performing a heating process so as to form a source/drain graphene contact from the silicon-carbide (SiC) semiconductor material in both the source and drain regions of the FinFET device and forming first and second source/drain contact structures that are conductively coupled to the source/drain graphene contact in the source region and the drain region, respectively, of the FinFET device.

A semiconductor device which can reduce power consumption and a method for manufacturing the same are provided. A semiconductor device comprises an Si (silicon) substrate, an SIC (silicon carbide) layer formed on the surface of the Si substrate, an AIN (aluminum nitride) layer formed on the surface of the SiC layer, an n-type GaN (gallium nitride) layer formed on the surface of the AIN layer, a first electrode formed at the surface side of the GaN layer, and a second electrode formed at the reverse face side of the Si substrate 1. The magnitude of electrical current which flows between the first electrode and the second electrode depends on electrical voltage between the first electrode and the second electrode.

A method for producing a composite silicon carbide structure comprises: providing an initial substrate of monocrystalline silicon carbide; depositing an intermediate layer of polycrystalline silicon carbide at a temperature higher than 1000° C. on the initial substrate, the intermediate layer having a thickness greater than or equal to 1.5 microns; implanting light ionic species through the intermediate layer to form a buried brittle plane in the initial substrate, delimiting the thin layer between the buried brittle plane and the intermediate layer, and depositing an additional layer of polycrystalline silicon carbide at a temperature higher than 1000° C. on the intermediate layer, the intermediate layer and the additional layer forming a carrier substrate, and separating the buried brittle plane during the deposition of the additional layer.

According to one embodiment, a semiconductor device is provided with a first single crystal layer, a polycrystalline layer provided on an entire surface of the first single crystal layer, and a second single crystal layer bonded to the polycrystalline layer. The coefficient of thermal expansion of the polycrystalline layer is greater than the coefficient of thermal expansion of the second single crystal layer, and is smaller than the coefficient of thermal expansion of a compound semiconductor layer which can be provided on the second single crystal layer using an intervening a buffer layer.

A support for a semiconductor structure includes a charge-trapping layer on a base substrate. The charge-trapping layer consists of a polycrystalline main layer and, interposed in the main layer or between the main layer and the base substrate, at least one intermediate polycrystalline layer composed of a silicon and carbon alloy or carbon. The intermediate layer has a resistivity greater than 1000 ohm.Math.cm.

A process for forming graphene, includes: depositing at least a first and a second metal onto a surface of silicon carbide (SiC), and heating the SiC and the first and second metals under conditions that cause the first metal to react with silicon of the silicon carbide to form carbon and at least one stable silicide. The corresponding solubilities of the carbon in the stable silicide and in the second metal are sufficiently low that the carbon produced by the silicide reaction forms a graphene layer on the SiC.

A silicon carbide semiconductor device, including a silicon carbide semiconductor substrate of a first conductivity type, a first silicon carbide semiconductor deposition layer of the first conductivity type, deposited on a front surface of the silicon carbide semiconductor substrate and having an impurity concentration that is lower than that of the silicon carbide semiconductor substrate, a base region of a second conductivity type, selectively provided in the first silicon carbide semiconductor deposition layer at a front surface thereof, and a second silicon carbide semiconductor deposition layer of the second conductivity type, deposited on the front surface of the first silicon carbide semiconductor deposition layer. The base region has an impurity concentration of 1×10.sup.18 to 1×10.sup.20/cm.sup.3 and a thickness of 0.3 to 1.0 μm. The second silicon carbide semiconductor deposition layer has a surface defect density of 3 defects/cm.sup.2.

A stack for a semiconductor device and a method for making the stack are disclosed. The stack includes a plurality of sacrificial layers in which each sacrificial layer has a first lattice parameter; and at least one channel layer that has a second lattice parameter in which the first lattice parameter is less than or equal to the second lattice parameter, and each channel layer is disposed between and in contact with two sacrificial layers and includes a compressive strain or a neutral strain based on a difference between the first lattice parameter and the second lattice parameter.

A 3C-SiC epitaxial layer is produced by a production method including: epitaxially growing a first 3C-SiC layer on a Si substrate; oxidizing the first 3C-SiC layer; removing an oxide film on a surface of the 3C-SiC layer; and epitaxially growing a second 3C-SiC layer on the 3C-SiC layer after the oxide film is removed.

In a step of calculating formation conditions for the second silicon carbide layer, a formation time of the second silicon carbide layer is calculated as a value obtained by multiplying a value obtained by dividing the second thickness by the first thickness, by the first formation time, and a flow rate of a second ammonia gas in a step of forming the second silicon carbide layer by epitaxial growth is calculated as a value obtained by multiplying a value obtained by dividing the second concentration by the first concentration, by the first flow rate.