Systems and methods disclosed and contemplated herein relate to manufacturing thin film semiconductors. Resulting thin film semiconductors are particularly suited for applications such as flexible optoelectronics and photovoltaic devices. Broadly, methods and techniques disclosed herein include high-temperature deposition techniques combined with lift-off in aqueous environments. These methods and techniques can be utilized to incorporate thin film semiconductors into substrates that have limited temperature tolerances.

What is provided is a transistor including a gate electrode, a gate insulating film, a semiconductor film, a source electrode, and a drain electrode, in which the gate insulating film is a laminated film in which a SiO.sub.x film and a SiC.sub.yN.sub.z film are alternately formed, the total number of films constituting the laminated film is 3 or more and 18 or less, and the thickness of each film constituting the laminated film is 25 nm or more and 150 nm or less.

A device includes a dielectric layer, a conductive layer, electrode layers and an oxide semiconductor layer. The dielectric layer has a first surface and a second surface opposite to the first surface. The conductive layer is disposed on the first surface of the dielectric layer. The electrode layers are disposed on the second surface of the dielectric layer. The oxide semiconductor layer is disposed in between the second surface of the dielectric layer and the electrode layers, wherein the oxide semiconductor layer comprises a material represented by formula 1 (In.sub.xSn.sub.yTi.sub.zM.sub.mO.sub.n). In formula 1, 0<x<1, 0≤y<1, 0<z<1, 0<m<1, 0<n<1, and M represents at least one metal.

A material deposition system comprises a dopant source containing at least one dopant precursor material, an inert gas source containing at least one noble gas, and a physical vapor deposition apparatus in selective fluid communication with the dopant source and the inert gas source. The physical vapor deposition apparatus comprises a housing structure, a target electrode, and a substrate holder. The housing structure is configured and positioned to receive at least one feed fluid stream comprising the at least one dopant precursor material and the at least one noble gas. The target electrode is within the housing structure and is in electrical communication with a signal generator. The substrate holder is within the housing structure and is spaced apart from the target electrode. A method of forming a microelectronic device, a microelectronic device, a memory device, and an electronic system are also described.

An object of the present invention is to provide a high-quality SiC semiconductor device. In order to solve the above problem, the present invention comprises a method for producing a SiC semiconductor device, comprising a growth step of forming a growth layer on a workpiece comprising SiC single crystals, a device formation step of forming at least a portion of a SiC semiconductor device in the growth layer, and a separation step of separating at least a portion of the SiC semiconductor device from the workpiece.

The present invention provides a semiconductor device, comprising: a substrate (10); a stack of III-nitride transition layers (11) disposed on the substrate (10), the stack of III-nitride transition layers (11) maintaining an epitaxial relationship to the substrate (10); a first III-nitride layer (121) disposed on the stack of III-nitride transition layers (11); and a second III-nitride layer (122) disposed on the first III-nitride layer (121), the second III-nitride layer (122) having a band gap energy greater than that of the first III-nitride layer (121), wherein the stack of III-nitride transition layers (11) comprises a first transition layer (111), a second transition layer (112) on the first transition layer (111), and a third transition layer (113) on the second transition layer (112), and wherein the second transition layer (112) has a minimum aluminium molar ratio among the first transition layer (111), the second transition layer (112) and third transition layer (113). The present invention also relates to a method of forming such semiconductor device. The semiconductor device according to the present invention advantageously has a dislocation density less than or equal to 1×10.sup.9 cm.sup.−2 in the first III-nitride layer (121).

A transistor device and the manufacturing methods are described. The device includes a gate structure having a gate layer and a ferroelectric layer, source and drain terminals, and a crystalline channel portion. The source and drain terminals are disposed at opposite sides of the gate structure. The crystalline channel portion extends between the source and drain terminals. The source and drain terminals are disposed on the crystalline channel portion and the gate structure is disposed on the crystalline channel portion. The crystalline channel portion includes a first material containing a Group III element and a Group V element, the gate layer includes a second material containing a Group III element and a rare-earth element, and the ferroelectric layer includes a third material containing a Group III element, a rare-earth element and a Group V element.

A semiconductor apparatus capable of reducing the leakage current in the reverse direction, and keeping characteristics thereof, even when using n type semiconductor (gallium oxide, for example) or the like having a low-loss at a high voltage and having much higher dielectric breakdown electric field strength than SiC is provided. A semiconductor apparatus includes a crystalline oxide semiconductor having a corundum structure as a main component, and an electric field shield layer and a gate electrode that are respectively laminated directly or through other layers on the n type semiconductor layer, wherein the electric field shield layer includes a p type oxide semiconductor, and is embedded in the n type semiconductor layer deeper than the gate electrode.

A manufacturing method of a semiconductor device includes the forming a first oxide over a substrate; depositing a first insulator over the first oxide; forming an opening reaching the first oxide in the first insulator; depositing a first oxide film in contact with the first oxide and the first insulator in the opening; depositing a first insulating film over the first oxide film by a PEALD method; depositing a first conductive film over the first insulating film; and removing part of the first oxide film, part of the first insulating film, and part of the first conductive film until a top surface of the first insulator is exposed to form a second oxide, a second insulator, and a first conductor. The deposition of the first insulating film is performed while the substrate is heated to higher than or equal to 300°.

An exemplary device includes a channel layer, a first epitaxial source/drain feature, and a second epitaxial source/drain feature disposed over a substrate. The channel layer is disposed between the first epitaxial source/drain feature and the second epitaxial source/drain feature. A metal gate is disposed between the first epitaxial source/drain feature and the second epitaxial source/drain feature. The metal gate is disposed over and physically contacts at least two sides of the channel layer. A source/drain contact is disposed over the first epitaxial source/drain feature. A doped crystalline semiconductor layer, such as a gallium-doped crystalline germanium layer, is disposed between the first epitaxial source/drain feature and the source/drain contact. The doped crystalline semiconductor layer is disposed over and physically contacts at least two sides of the first epitaxial source/drain feature. In some embodiments, the doped crystalline semiconductor layer has a contact resistivity that is less than about 1×10.sup.−9 Ω-cm.sup.2.