When a nitride semiconductor layer into which impurity ions have been implanted is subjected to annealing after a protective film is provided on the nitride semiconductor layer, vacancy defects may be disadvantageously prevented from escaping outside through the surface of the nitride semiconductor layer and disappearing. A manufacturing method of a semiconductor device including a nitride semiconductor layer is provided. The manufacturing method includes implanting impurities into the nitride semiconductor layer, performing a first annealing on the nitride semiconductor layer at a first temperature within an atmosphere of a nitrogen atom containing gas without providing a protective film on the nitride semiconductor layer, forming the protective film on the nitride semiconductor layer after the first annealing, and after the protective film is formed, performing a second annealing on the nitride semiconductor layer at a second temperature that is higher than the first temperature.

An embodiment includes a III-V material based device, comprising: a first III-V material based buffer layer on a silicon substrate; a second III-V material based buffer layer on the first III-V material based buffer layer, the second III-V material including aluminum; and a III-V material based device channel layer on the second III-V material based buffer layer. Another embodiment includes the above subject matter and the first and second III-V material based buffer layers each have a lattice parameter equal to the III-V material based device channel layer. Other embodiments are included herein.

A semiconductor device is provided that includes a first of a source region and a drain region comprised of a first semiconductor material, wherein an etch stop layer of a second semiconductor material present within the first of the source region and the drain region. A channel semiconductor material is present atop the first of the source region and the drain region. A second of the source and the drain region is present atop the channel semiconductor material. The semiconductor device may be a vertically orientated fin field effect transistor or a vertically orientated tunnel field effect transistor.

An n-MOS transistor device and method for forming such a device are disclosed. The n-MOS transistor device comprises a semiconductor substrate with one or more replacement active regions formed above the substrate. The replacement active regions comprise a first III-V semiconductor material. A gate structure is formed above the replacement active regions. Source/Drain (S/D) recesses are formed in the replacement active region adjacent to the gate structure. Replacement S/D regions are formed in the S/D recesses and comprise a second III-V semiconductor material having a lattice constant that is smaller than the lattice constant of the first III-V semiconductor material. The smaller lattice constant of the second III-V material induces a uniaxial-strain on the channel formed from the first III-V material. The uniaxial strain in the channel improves carrier mobility in the n-MOS device.

A method of manufacturing a semiconductor device includes forming a first semiconductor layer on a substrate, forming a stack of semiconductor layer structures on the first semiconductor layer, and etching the stack to form a fin structure. Each of the semiconductor layer structures includes a first insulator layer and a second semiconductor layer on the first insulator layer. The first and second semiconductor layers have the same semiconductor compound. The fin structure according to the novel method includes one or more insulator layers to achieve a higher on current/off current ratio, thereby improving the device performance relative to conventional fin structures without the insulator layers.

An HEMT device, comprising: a semiconductor body including a heterojunction structure; a dielectric layer on the semiconductor body; a gate electrode; a drain electrode, facing a first side of the gate electrode; and a source electrode, facing a second side opposite to the first side of the gate electrode; an auxiliary channel layer, which extends over the heterojunction structure between the gate electrode and the drain electrode, in electrical contact with the drain electrode and at a distance from the gate electrode, and forming an additional conductive path for charge carriers that flow between the source electrode and the drain electrode.

A field effect transistor (FET) including a substrate, a plurality of semiconductor epitaxial layers deposited on the substrate, and a heavily doped gate layer deposited on the semiconductor layers. The FET also includes a plurality of castellation structures formed on the heavily doped gate layer and being spaced apart from each other, where each castellation structure includes at least one channel layer. A gate metal is deposited on the castellation structures and between the castellation structures to be in direct electrical contact with the heavily doped gate layer. A voltage potential applied to the gate metal structure modulates the at least one channel layer in each castellation structure from an upper, lower and side direction.

A substrate with a (001) orientation is provided. A gallium arsenide (GaAs) layer is epitaxially grown on the substrate. The GaAs layer has a reconstruction surface that is a 4×6 reconstruction surface, a 2×4 reconstruction surface, a 3×2 reconstruction surface, a 2×1 reconstruction surface, or a 4×4 reconstruction surface. Via an atomic layer deposition process, a single-crystal structure yttrium oxide (Y.sub.2O.sub.3) layer is formed on the reconstruction surface of the GaAs layer. The atomic layer deposition process includes water or ozone gas as an oxygen source precursor and a cyclopentadienyl-type compound as an yttrium source precursor.

An integrated circuit device may include a substrate including a main surface, a compound semiconductor nanowire extending from the main surface in a first direction perpendicular to the main surface and including a first section and a second section alternately arranged in the first direction, a gate electrode covering the first section, and a gate dielectric layer between the first section and the gate electrode. The first section and the second section may have the same composition as each other and may have different crystal phases from each other

A III-N device is described with a III-N material layer, an insulator layer on a surface of the III-N material layer, an etch stop layer on an opposite side of the insulator layer from the III-N material layer, and an electrode defining layer on an opposite side of the etch stop layer from the insulator layer. A recess is formed in the electrode defining layer. An electrode is formed in the recess. The insulator can have a precisely controlled thickness, particularly between the electrode and III-N material layer.