In some aspects, methods of forming a metal sulfide thin film are provided. According to some methods, a metal sulfide thin film is deposited on a substrate in a reaction space in a cyclical process where at least one cycle includes alternately and sequentially contacting the substrate with a first vapor-phase metal reactant and a second vapor-phase sulfur reactant. In some aspects, methods of forming a three-dimensional architecture on a substrate surface are provided. In some embodiments, the method includes forming a metal sulfide thin film on the substrate surface and forming a capping layer over the metal sulfide thin film. The substrate surface may comprise a high-mobility channel.

A technique of manufacturing a semiconductor device of stable operation is provided. There is provided a method of manufacturing a semiconductor device comprising a first process of forming an insulating film from a nitrogen-containing organic metal used as raw material, on a semiconductor layer by atomic layer deposition; a second process of processing the insulating film by oxygen plasma treatment in an atmosphere including at least one of oxygen and ozone; and a third process of processing the insulating film by heat treatment in a nitrogen-containing atmosphere, after the second process.

A high-k gate dielectric interface with a group III-V semiconductor surface of a non-planar transistor channel region is non-directionally doped with nitrogen. In nanowire embodiments, a non-directional nitrogen doping of a high-k gate dielectric interface is performed before or concurrently with a conformal gate electrode deposition through exposure of the gate dielectric to liquid, vapor, gaseous, plasma, or solid state sources of nitrogen. In embodiments, a gate electrode metal is conformally deposited over the gate dielectric and an anneal is performed to uniformly accumulate nitrogen within the gate dielectric along the non-planar III-V semiconductor interface.

A field effect transistor according to the present invention includes a semiconductor layer including a groove, an insulating film formed on an upper surface of the semiconductor layer and having an opening above the groove and a gate electrode buried in the opening to be in contact with side surfaces and a bottom surface of the groove and having parts being in contact with an upper surface of the insulating film on both sides of the opening, wherein the gate electrode has a T-shaped sectional shape in which a width of an upper end is larger than a width of the upper surface of the insulating film.

An enhanced switch device and a manufacturing method therefor. The method comprises: providing a substrate, and forming a nitride transistor structure on the substrate; fabricating and forming a dielectric layer on the nitride transistor structure, on which a gate region is defined; forming a groove structure on the gate region; depositing a p-type semiconductor material in the groove; removing the p-type semiconductor material outside the gate region on the dielectric layer; etching the dielectric layer in another position than the gate region on the dielectric layer to form two ohmic contact regions; and forming a source electrode and a drain electrode on the two ohmic contact regions, respectively.

A technique of reducing the complication in manufacture is provided. There is provided a semiconductor device comprising an n-type semiconductor region made of a nitride semiconductor containing gallium; a p-type semiconductor region arranged to be adjacent to and in contact with the n-type semiconductor region and made of the nitride semiconductor; a first electrode arranged to be in ohmic contact with the n-type semiconductor region; and a second electrode arranged to be in ohmic contact with the p-type semiconductor region. The first electrode and the second electrode are mainly made of one identical metal. The identical metal is at least one metal selected from the group consisting of palladium, nickel and platinum. A concentration of a p-type impurity in the n-type semiconductor region is approximately equal to a concentration of the p-type impurity in the p-type semiconductor region. A difference between a concentration of an n-type impurity and the concentration of the p-type impurity in the n-type semiconductor region is not less than 1.0×10.sup.19 cm.sup.−3.

The present disclosure provides a semiconductor structure in accordance with some embodiments. The semiconductor structure includes a semiconductor feature, a passivation layer that includes indium sulfide formed over a surface of the semiconductor feature. More particularly, the surface of the semiconductor feature comprises indium-based III-V compound semiconductor material.

A semiconductor device includes a first semiconductor layer made of a nitride semiconductor and formed on a substrate, a second semiconductor layer made of a material including InAlN and formed on the first semiconductor layer, an insulator layer formed by an oxidized surface part of the second semiconductor layer, a gate electrode formed on the insulator layer, and a source electrode and a drain electrode respectively formed on the first or second semiconductor layer.

Present embodiments provide for a FinFET and fabrication method thereof. The fabrication method includes two selective etching processes to form the channel. The FinFET includes a substrate, a shallow trench isolation (STI) layer, a buffer layer, a III-V group material, an oxide-isolation layer, a high-K dielectric layer and a conductor material. The STI is formed on the substrate with a trench. The buffer layer is formed on the substrate in the trench. The III-V group material is formed on the buffer layer in vertical stacked bowl shape. The oxide-isolation layer is formed between the substrate and the III-V group material. The high-K dielectric layer is formed on the STI layer and surrounding the III-V group material. The conductor material is formed surrounding the high-K dielectric layer.

A lower resist (2) is applied on a semiconductor substrate (1). An upper resist (3) is applied on the lower resist (2). A first opening (4) is formed in the upper resist (3) by exposure and development and the lower resist (2) is dissolved with a developer upon the development to form a second opening (5) having a width wider than that of the first opening (4) below the first opening (4) so that a resist pattern (6) in a shape of an eave having an undercut is formed. Baking is performed to thermally shrink the upper resist (3) to bent an eave portion (7) of the upper resist (3) upward. After the baking, a metal film (8) is formed on the resist pattern (6) and on the semiconductor substrate (1) exposed at the second opening (5). The resist pattern (6) and the metal film (8) is removed on the resist pattern (6) and the metal film (8) is left on the semiconductor substrate (1) as an electrode (9).