High electron mobility transistors are provided which comprise a III-Nitride semiconductor layer comprising a III-Nitride semiconductor, in contact with a gallium oxide semiconductor layer comprising gallium oxide, forming an interface therebetween.

A semiconductor structure comprises a plurality of gate structures alternately stacked with a plurality of channel layers, and a plurality of epitaxial source/drain regions connected to the plurality of channel layers. The plurality of channel layers are connected to the plurality of epitaxial source/drain regions via a plurality of epitaxial extension regions. Respective pairs of adjacent channel layers of the plurality of channel layers are connected to a given one of the plurality of epitaxial source/drain regions via respective ones of the plurality of epitaxial extension regions.

A nano-FET and a method of forming is provided. In some embodiments, a nano-FET includes an epitaxial source/drain region contacting ends of a first nanostructure and a second nanostructure. The epitaxial source/drain region may include a first semiconductor material layer of a first semiconductor material, such that the first semiconductor material layer includes a first segment contacting the first nanostructure and a second segment contacting the second nanostructure, wherein the first segment is separated from the second segment. A second semiconductor material layer is formed over the first segment and the second segment. The second semiconductor material layer may include a second semiconductor material having a higher concentration of dopants of a first conductivity type than the first semiconductor material layer. The second semiconductor material layer may have a lower concentration percentage of silicon than the first semiconductor material layer.

A superlattice structure includes a substrate. A first superlattice stack is disposed on the substrate. The first superlattice stack includes a first superlattice layer, a second superlattice layer and a third superlattice layer disposed from bottom to top. Three stress relaxation layers respectively disposed between the first superlattice layer and the second superlattice layer, the second superlattice layer and the third superlattice layer and on the third superlattice layer. Each of the stress relaxation layers includes a group III-V compound layer. The thickness of each of the stress relaxation layers should be greater than a relaxation critical thickness.

In a silicon carbide substrate including: a SiC substrate; and a first semiconductor layer, a second semiconductor layer and a drift layer that are epitaxial layers sequentially formed on the SiC substrate, an impurity concentration of the first semiconductor layer is lower than impurity concentrations of the SiC substrate and the second semiconductor layer, and the second semiconductor layer is formed to have a high impurity concentration or a large thickness.

An apparatus and a method for forming a 3-D NAND device are disclosed. The method of forming the 3-D NAND device may include forming a plug fill and a void. Advantages gained by the apparatus and method may include a lower cost, a higher throughput, little to no contamination of the device, little to no damage during etching steps, and structural integrity to ensure formation of a proper stack of oxide-nitride bilayers.

A surface-emitting laser element includes: a first guide layer including a photonic crystal layer that is formed on a c plane of a group-3 nitride semiconductor and includes air holes arranged with two-dimensional periodicity in a plane parallel to the photonic crystal layer, and an embedding layer that is formed on the photonic crystal layer and closes the air holes; an active layer formed on the first guide layer; and a second guide layer formed on the active layer, wherein an air hole set including at least a main air hole and a sub-air hole smaller in size than the main air hole is arranged at each square lattice point in the plane parallel to the photonic crystal layer, and wherein the main air hole has a regular-hexagonal prism shape, a long-hexagonal prism shape, or an elliptic cylindrical shape with a major axis parallel to a <11-20> axis.

A method and a wafer processing furnace for forming a doped polysilicon layer on a plurality of substrates is provided. In a preferred embodiment, the method comprises providing a plurality of substrates to a process chamber. It also comprises executing a deposition cycle comprising providing a silicon-containing precursor to the process chamber thereby depositing, on the plurality of substrates, an undoped silicon layer until a pre-determined thickness is reached and providing the process chamber with a flow of a dopant precursor gas without providing the silicon-containing precursor to the process chamber. The method also comprises performing a heat treatment process, thereby forming the doped polysilicon layer.

Provided is a semiconductor substrate with a balance stress. The semiconductor substrate includes a ceramics base, a nucleation layer and a first buffer layer doped with a first dopant. The ceramics base has an off-cut angle other than 0 degree. The nucleation layer is disposed on the ceramics base. The first buffer layer is disposed on the nucleation layer. The first dopant includes C, Fe or a combination thereof. The first buffer layer provides compressive stress to the ceramic base. The concentration of the first dopant in the first buffer layer is increased away from the ceramics base. The curvature of the semiconductor substrate is between 16 km.sup.−1 and −16 km.sup.−1.

A semiconductor structure includes a buffer layer, a channel layer, a barrier layer, a doped compound semiconductor layer, and a composition gradient layer. The buffer layer is disposed on a substrate, the channel layer is disposed on the buffer layer, the barrier layer is disposed on the channel layer, the doped compound semiconductor layer is disposed on the barrier layer, and the composition gradient layer is disposed between the barrier layer and the doped compound semiconductor layer. The barrier layer and the composition gradient layer include a same group III element and a same group V element, and the atomic percentage of the same group III element in the composition gradient layer is gradually increased in the direction from the barrier layer to the doped compound semiconductor layer. A high electron mobility transistor and a fabrication method thereof are also provided.