A semiconductor laminate at least including: a base; a buffer layer; and a crystalline metal oxide semiconductor film containing at least one metal element and having a corundum structure, the semiconductor laminate having the buffer layer on a main surface of the base directly or via another layer, the semiconductor laminate having the crystalline metal oxide semiconductor film on the buffer layer. The buffer layer is a laminate structure of a plurality of buffer films each with a different composition, and at least two buffer films of the plurality of buffer films have a film thickness of 200 nm or more and 650 nm or less.

A semiconductor device for high power application in which a novel semiconductor material having high mass productivity is provided. An oxide semiconductor film is formed, and then, first heat treatment is performed on the exposed oxide semiconductor film in order to reduce impurities such as moisture or hydrogen in the oxide semiconductor film. Next, in order to further reduce impurities such as moisture or hydrogen in the oxide semiconductor film, oxygen is added to the oxide semiconductor film by an ion implantation method, an ion doping method, or the like, and after that, second heat treatment is performed on the exposed oxide semiconductor film.

Provided is a semiconductor device A including: a first electrode 10; a second electrode 20; a semiconductor layer 30 in contact with the first electrode 10 and the second electrode 20; and a protective layer 40 configured to cover at least a part of a surface of the semiconductor layer 30, wherein the protective layer 40 includes a spinel oxide.

A method for manufacturing semiconductor device according to an embodiment includes: forming a first metal oxide layer containing aluminum as a main component above a substrate; forming an oxide semiconductor layer above the first metal oxide layer; forming a gate insulating layer above the oxide semiconductor layer; forming a second metal oxide layer containing aluminum as a main component above the gate insulating layer; performing a heat treatment in a state where the second metal oxide layer is formed above the gate insulating layer; removing the second metal oxide layer after the heat treatment; and forming a gate electrode above the gate insulating layer.

A method for producing a gallium oxide semiconductor film by a mist CVD method, including, a mist-forming step in which a raw material solution containing gallium is misted in a mist-forming unit to generate mist, a carrier gas supply step of supplying a carrier gas for transferring the mist to the mist-forming unit, a transferring step of transferring the mist from the mist-forming unit to a film forming chamber using the carrier gas via a supply pipe connecting the mist-forming unit and the film forming chamber, a rectification step of rectifying flow of the mist and the carrier gas supplied to a surface of a substrate in the film forming chamber so as to flow along the surface of the substrate, a film forming step of heat-treating the rectified mist to form a film on the substrate, and an exhaust step of exhausting waste gas upward from the substrate.

Various embodiments pertain to a high mobility transistor element resulting from IGTO oxide semiconductor crystallization, and a production method for same, the transistor element comprising a substrate and a crystalline IGTO channel layer disposed on the substrate, and being produced by converting a non-crystalline IGTO channel layer provided on the substrate to a crystalline IGTO channel layer.

A method for manufacturing an epitaxial substrate includes the steps of: epitaxially growing a group III nitride semiconductor layer on a substrate; removing the substrate from a growth furnace; irradiating a surface of the group III nitride semiconductor layer with ultraviolet light while exposing the surface to an atmosphere containing oxygen; and measuring a sheet resistance value of the group III nitride semiconductor layer.

A thin-film transistor using an inorganic semiconductor layer as a channel layer and a method of manufacturing the same are disclosed. The channel layer is patterned, and an inorganic photosensitive layer is coated for the patterning. The inorganic photosensitive layer is formed as a patterned inorganic photosensitive layer through irradiation with extreme ultraviolet light or electron beams. When heat treatment is performed on an inorganic photosensitive layer pattern, the inorganic photosensitive layer pattern is modified into the patterned inorganic semiconductor layer. Accordingly, no separate photoresist is required to form the channel layer, and an etching process using a formed photoresist pattern is not necessary, so that process efficiency is improved.

A semiconductor device includes an oxide semiconductor stack, a first gate, a first contact structure, and a second contact structure. The oxide semiconductor stack includes an n-type oxide semiconductor layer and a p-type oxide semiconductor layer stacked on each other. The first gate is over the oxide semiconductor stack. The first contact structure and the second contact structure are at opposite sides of the first gate and electrically connected to the oxide semiconductor stack.

A transistor may be provided by forming, in a forward order or in a reverse order, a gate electrode, a metal oxide liner, a gate dielectric, and an active layer over a substrate, and by forming a source electrode and a drain electrode on end portions of the active layer. The metal oxide liner comprises a thin semiconducting metal oxide material that functions as a hydrogen barrier material.